Assay method for group transfer reactions

ABSTRACT

The present invention relates to methods for detecting, quantifying and high throughput screening of donor-products and the catalytic activities generating the donor-products in group-transfer reactions. The invention further provides immunoassays, antibodies and kits that may be used to practice the methods of the invention.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. application Ser. No. 10/769,578 filed Jan. 30, 2004 which claims the benefit of U.S. Provisional Application No. 60/443,746 filed Jan. 30, 2003, all of which are incorporated by reference here in their entirety.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

This invention was made with United States government support awarded by the National Institutes of Health under grant numbers: GM59542, GM69258 and CA 110535. The United States government has certain rights in this invention.

TECHNICAL FIELD

The present invention relates to group transfer reaction methodologies. The invention provides methods for the detection and quantification of donor-products and the catalytic activities generating the donor-products in group transfer reactions. The invention also provides methods for high throughput screening to identify acceptor substrates, inhibitors, or activators of enzymes catalyzing group transfer reactions. The invention further provides immunoassays, antibodies and related kits for practicing the invention.

BACKGROUND OF THE INVENTION

There are many important biological reactions where the substrates are modified by chemical groups that are donated by other substrates, known as activated donor molecules. These biological reactions are broadly recognized as “group transfer reactions” and have the general reaction:

-   -   donor-X+acceptor→donor-product+acceptor-X.         Typically, donor-X, the activated donor molecule, is a         nucleotide attached to a covalent adduct. The donor-X is         activated by formation of a phosphoester bond in the nucleotide         donor. Also the acceptor substrates can include small molecules         or macromolecules such as proteins or nucleic acids. Products of         this reaction are the modified acceptor, acceptor-X and the         donor-product molecule.

There are many enzymes that catalyze group transfer reactions such as for example kinases, which use ATP to donate a phosphate group; sulfotransferases (SULTs), which use phosphoadenosine-phosphosulfate (PAPS) to donate a sulfonate group; UDP-glucuronosyltransferases (UGTs), which use UDP-glucuronic acid to transfer a glucuronic acid group; methyltransferases, which use s-adenosyltransferase to donate a methyl group; acetyl transferase, which use acetyl coenzymeA to donate an acetyl group; and ADP-ribosyltransferases, which use nicotinamide adenine dinucleotide (NAD) to donate an ADP-ribose group. Thus, many of the enzymes catalyzing group transfer reactions are of interest to pharmaceutical companies.

Automated high throughput screening (HTS) assays are the paradigm for identifying interactions of potential drug molecules with proteins in a drug discovery setting, and this format requires simple, robust molecular assays, preferably with a fluorescent or chemiluminescent readout. The most suitable format for HTS is a homogenous assay, (e.g., “single addition” or “mix and read” assay), which does not require any manipulation after the reaction is initiated and the assay signal can be monitored continuously. Despite their importance from a drug discovery perspective, the incorporation of group transfer enzymes into pharmaceutical HTS programs is being slowed or prevented for a number of reasons: a) homogenous assay methods are not currently available, b) the detection methods used place serious limits on the utility of the assay, and c) the non-generic nature of the assay requires the development of many specific detection reagents to test diverse acceptor substrates.

The approach currently used to identify sulfotransferase substrates or inhibitors requires the use of radioactivity and involves cumbersome post-reaction separation steps, such as precipitation or chromatography. For instance, ³⁵S-PAPS is used in a sulfotransferase reaction and the labeled product is quantified by scintillation counting after selective precipitation of unreacted ³⁵S-PAPS (Foldes, A. and Meek, J. L., Biochim Biophys Acta, 1973, 327:365-74). This approach is not desirable in a high throughput screening (HTS) format because of the high radiation disposal costs and because the incorporation of separation steps complicates the automation process. Other SULT assays have been developed using colorimetric and fluorescent means, but they are dependent on the use of a specific acceptor substrate for detection, so their use is limited to a single SULT isoform, and they cannot be used to screen for diverse substrates (Burkart, M. D. and Wong, C. H., Anal Biochem, 1999, 274:131-7; Frame, L. T., et al., Drug Metab Dispos, 2000, 28:1063-8). As a result, SULT interaction studies are currently not included during the preclinical development of drugs. Also UGTs are currently assayed using radiolabeled donor molecules and require post-reaction separation steps such as thin layer chromatography (TLC) or high pressure liquid chromatography (HPLC) which seriously hampers preclinical HTS programs (Ethell, B. T., et al., Anal Biochem, 1998, 255:142-7). Likewise, traditionally, kinases have been assayed by filter capture or precipitation of radiolabeled polypeptide substrates produced using ³²P-ATP or ³³P-ATP as donor. However, since this method requires a separation step such as filtering or centrifugation, it cannot be easily adapted to an automated HTS format. Surface proximity assays (SPA) allow radioassays in a multiwell format with no separation (Mallari, R., et al., J Biomol Screen, 2003, 8:198-204) but their use by pharmaceutical companies is declining because of the disposal and regulatory costs of handling radioisotopes.

Because of the high level of interest in developing kinase inhibitor drugs, there has been a great deal of effort among scientists to develop improved assay methods for this enzyme family. Homogenous assay methods have been developed, in which highly specific reagents are used to detect the reaction products in the presence of the other components of the reaction using a light-based readout, such as fluorescence or chemiluminescence. The most common homogenous approach used for kinase assays is immunodetection of phosphopeptide products exhibiting different fluorescence properties (Zaman, G. J., et al., Comb Chem High Throughput Screen, 2003, 6:313-20). In this method, phosphorylation of substrate peptide leads to displacement of a fluorescent phosphopeptide tracer from an anti-phosphopeptide antibody and causes a change in its fluorescence properties. This basic approach has been adapted to several different readout modes used for competitive immunoassays including Fluorescence polarization (FP) (Parker, G. J., et al., J Biomol Screen, 2000, 5:77-88); time resolved fluorescence (Xu, K., et al., J Biochem Mol Biol, 2003, 36:421-5); fluorescence lifetime discrimination (Fowler, A., et al., Anal Biochem, 2002, 308:223-31); and chemiluminescence (Eglen, R. M. and Singh, R., Comb Chem High Throughput Screen, 2003, 6:381-7).

The shortcoming with this approach is the requirement for phosphopeptide-specific antibodies. Though generic phosphotyrosine antibodies are common, phosphoserine and phosphothreonine antibodies are notoriously difficult to produce and only recognize phospho-serine or -threonine in the context of specific flanking amino acids (Eglen and Singh, 2003). There are over 400 kinases in humans and their specificity for phosphorylation sites vary widely. Thus, different antibodies are needed for assaying diverse kinases or profiling acceptor substrates. This greatly complicates the incorporation of new kinases into HTS, especially if their substrate specificity is not well defined. It also creates analysis problems in comparing data among kinases with different substrate selectivities, because the output of the assay depends on the particular antibody (Ab)-phosphopeptide pair used. Although efforts to develop generic phospho-serine antibodies identify more generic kinase substrates continue (Sills, M. A., et al., J Biomol Screen, 2002, 7:191-214), research in this direction has not been very successful to date.

A number of alternative approaches have been developed to circumvent the problem of context-specific Ab-phosphopeptide interactions, including use of metal complexes to bind phosphopeptides (Scott, J. E. and Carpenter, J. W., Anal Biochem, 2003, 316:82-91) and the use of modified ATP analogs that allow covalent tagging of phosphopeptide products (Allison Miller-Wing, E. G., Barbara Armstrong, Lindsey Yeats, Ram Bhatt, Frank Gonzales, and Steven Gessert., SBS 9th Annual Conference and Exhibition, Portland, Oreg., 2003). Chemical phosphate binding reagents suffer from background binding to nucleotide phosphates, requiring the use of very low, non-physiological levels of ATP and limiting assay flexibility. Modified nucleotides do not provide a generic format because the ability to use the ATP analogs as donors varies among kinases, requiring the development of a number of different analogs. Also competition of inhibitors with the modified nucleotides at the kinase ATP binding site—the most frequent site for kinase inhibitor binding—does not reflect the physiological situation. Differences in protease sensitivity caused by peptide phosphorylation have also been exploited in developing fluorescence based kinase assays (Kupcho, K., et al., Anal Biochem, 2003, 317:210-7), but these assays are not truly homogenous; i.e. they require the post-reaction addition of developing protease reagents. In addition, the applicability of this method is limited to peptides where kinase and protease specificity overlap.

There are also a few methods that are dependent on interaction of reaction products with specific multiwell plate chemistries, but these are not truly homogenous in that they require post reaction reagent additions and/or processing. Also the requirement for specialized instrumentation for processing and/or detection does not fit with the open architecture desired by most pharmaceutical HTS platforms.

Furthermore, microfluidics-based kinase assays that rely on electrophoretic separation of reaction products have been developed (Xue, Q., et al., Electrophoresis, 2001, 22:4000-7). In these assays, phosphorylated peptide products are electrophoretically separated from the non-phosphorylated acceptor substrates, thus eliminating the need for specialized detection reagents. However, in practice, the kinase assays are often run in multiwell plates and then the products are transferred to microfluidic devices for separation—a cumbersome process for an HTS format.

In summary, the non-generic nature of the current group transfer assays is resulting in significant expense and delays for drug discovery because of the need to develop assays for individual enzymes or small subgroups within a family. Also, because many of the current assays are based on modification and detection of specific tagged acceptors, there is limited ability for testing different acceptor substrates. Often the tagged acceptor substrates used are different from the substrates that are phosphorylated in vivo, thus the physiological relevance of the assay is questionable. In addition, a major concern in the pharmaceutical industry is that because of the non-generic nature of the current assays, investigators are sometimes forced to use different methods for different kinases. However, studies have shown that there are significant differences in the pharmaceutical targets identified using different assays methods (Sills, M. A., et al., J Biomol Screen, 2002, 7:191-214), which is a significant problem for profiling inhibitor selectivity across several kinases. These shortcomings of the existing HTS assay methods for group transfer reactions are hampering the rapid analysis of important enzyme families in pharmaceutical drug discovery programs.

Other existing approaches for assaying group transfer reactions have been to enable screening of diverse chemicals as substrates for group transfer reactions by detecting the donor molecule product, because it is the same regardless of the acceptor being modified. Detection of the donor product has been thought to provide the basis of a generic assay method, ADP is always a product of a kinase reaction and phosphoadenosine-phosphate (PAP) is always the product of a sulfotransferase reaction. Detection of these products, however, is complicated because the cleaved mono- and di-nucleotides cannot be differentiated from the activated donor molecules based on absorbance or fluorescence properties because for example ADP has the same fluorescence and absorbance properties as ATP. Separation of the donor product from the donor can be effected using chromatographic methods, such as thin layer chromatography or high pressure liquid chromatography, but incorporation of these methods into an HTS format is cumbersome.

To circumvent this difficulty, detection of the donor product has been achieved by using additional enzymes to generate a detectable product from the primary reaction product—the cleaved mono- or di-nucleotide; this is known as an enzyme coupled reaction. For instance, enzymes and other small molecules can be used for ADP-dependent generation of NADPH, which is detected by absorbance or fluorescence at 340 nm (Walters, W. P. and Namchuk, M., Nat Rev Drug Discov, 2003, 2:259-66). An enzyme coupled reaction has also been developed for UGTs, another type of group transfer enzyme (Mulder, G. J. and van Doorn, A. B., Biochem J, 1975, 151:131-40). However, the optical interference of drug compounds with absorbance assays, especially in the ultra violet, is a widely recognized problem with this approach. Another shortcoming of this approach is that all of the enzymes used to couple the detection are subject to potential inhibition from the chemicals being screened.

Another generic approach is to monitor ATP consumption using Luciferase as a reporter to detect protein kinase activity. An example of this method was disclosed by Crouch et al., in U.S. Pat. No. 6,599,711. Their method entailed determining the activity of a protein kinase to be tested by adding a substrate capable of being phosphorylated by the protein kinase to a solution having ATP and a protein kinase to be tested, and another solution having ATP in the absence of the kinase to be tested. The concentration or the rate of time change of ATP and/or ADP was then measured using bioluminescence. However this assay is not optimal because it relies on small decreases in a high initial signal. The need to keep ATP concentrations low to minimize background results in nonlinear reaction kinetics if assay conditions are not carefully controlled. In a related method, competition binding assays using fluorescent ATP analogs have also been developed, but these do not give a measure of enzyme catalytic activity, thus are of limited utility.

The use of enzymes that catalyze group transfer reactions into HTS assays has been hampered by the lack of universal, homogenous assay methods that are not subject to interference from molecules in pharmaceutical drug libraries. Accordingly, it would generally be desirable to provide universal methods for assaying enzymes involved in group transfer reactions that are well suited for HTS drug discovery.

BRIEF SUMMARY OF THE INVENTION

To enable facile incorporation of important group transfer enzymes into HTS assays, applicants have developed assays based on homogenous immunodetection of the donor product. The general equation for the group transfer reaction is: donor-X+acceptor→donor-product+acceptor−X, wherein the donor-product is detected by the general detection reaction: first complex+donor-product→second complex+displaced detectable tag. Because the donor product is the same for all enzymes that catalyze a given type of group transfer reaction, the same detection reagents can be used for all the members within a family of group transfer enzymes and with any acceptor substrate. The assay products can be detected using homogenous fluorescence or chemiluminescence methods which are not subject to significant interference or background signal from molecules in pharmaceutical drug libraries.

Thus, the present invention is summarized as methods and components thereof for detecting the activity of and screening acceptor substrates, inhibitors, or activators of enzymes catalyzing group transfer reactions to facilitate the development of more selective and therapeutic drugs. This is accomplished through a highly selective antibody used to bind the donor product of the group transfer reaction. Antibody-antigen interactions can be detected in a number of ways that have already been described by others. The detection mode applicants have used to put the method into practice is a competitive fluorescence polarization immunoassay (FPIA), because it is well suited for pharmaceutical HTS assays. With this detection mode, enzymatically generated donor product displaces a fluorescent derivative of the donor product, called a tracer, from an antibody resulting in a decrease in tracer fluorescence polarization. The key reagents for the assay are an antibody that binds with high selectivity to the donor product, and not to the uncleaved donor molecule, and a tracer—a fluorescent derivative of the donor product that retains its structure sufficiently to bind the antibody. The invention provides a novel assay for detecting and quantifying activity for enzymes that catalyze group transfer reactions using diverse substrates. The invention also provides a method of screening for substrates, inhibitors, or activators of the group transfer reactions.

In one aspect, the invention provides a method of detecting a donor-product of a group transfer reaction, the method including reacting an activated form of a donor with an acceptor in the presence of a catalytically active enzyme; forming the donor-product and an acceptor-X; contacting the donor-product with a first complex comprising a detectable tag capable of producing an observable; competitively displacing the detectable tag of the first complex by the donor product to generate a second complex and a displaced detectable tag; and detecting a change in the observable produced by the detectable tag in the first complex and the displaced detectable tag.

In another aspect, the invention provides an antibody produced against a donor product of a group transfer reaction, wherein the antibody has the ability to preferentially distinguish between a donor-product and a donor in the presence of a high donor concentration.

In this aspect of the invention, the antibody is generated using an immunogen made from a nucleotide conjugated to a carrier protein. The conjugation between the nucleotide and the carrier protein occurs at the N6 amino, C8 or C2 positions of adenine; the C5 or C6 positions of uridine, thymidine or cytidine; or the 2′ or 3′ OH of ribose.

Also, in this aspect, the immunogen includes a linker region between the nucleotide and the carrier protein having a chemical formula of NH₂-X-Z, wherein X is a saturated or unsaturated chain of 2 to 20 carbons and Z is a functional group capable of covalently binding to a protein, and wherein the group includes an NH₂, SH, COOH or activated derivatives of COOH, such as succinimide or maleimide.

In yet another aspect, the invention provides a homogeneous competitive binding assay for a donor product of a group transfer reaction, the assay includes combining the donor-product with a tracer and a macromolecule to provide a mixture, the macromolecule being specific for the donor product, the tracer comprising the donor-product conjugated to a fluorophore, the tracer being able to bind to the macromolecule to produce a detectable change in fluorescence polarization; measuring the fluorescence polarization of the mixture to obtain a measured fluorescence polarization; and comparing the measured fluorescence polarization with a characterized fluorescence polarization value, the characterized fluorescence polarization value corresponding to a known donor-product concentration.

In yet another aspect, the invention provides assay kits for characterizing a donor-product from a group transfer reaction. The assay kit includes a macromolecule and a tracer, each in an amount suitable for at least one homogeneous fluorescence polarization assay for donor-product, wherein the macromolecule is a an antibody or an inactivated enzyme. The kit also includes a stabilizing reagent, preferably EGTA and a quenching reagent, preferably sodium vanadate.

In another aspect, the invention provides a tracer compound for use in a homogenous competitive binding assay to detect a donor-product of a group transfer reaction; wherein the tracer comprises a fluorophore conjugated to a nucleotide.

In this aspect, the fluorophore is conjugated to a nucleotide through a position selected from the group consisting of an N6 amino, a C8 or a C2 position of adenine, a C5 or C6 position of uridine, thymidine or cytidine, and a 2′ or 3′ OH position of ribose. Also, a linker may be positioned between the fluorophore and the nucleotide. The linker includes a chemical formula of NH₂-X-Z; wherein X is a saturated or unsaturated chain of 2 to 20 carbons and Z is a functional group capable of covalently binding to a protein; and wherein the group includes an NH₂, SH, COOH or activated derivatives of COOH, such as succinimide or maleimide.

In a related aspect, the invention provides a chemical linker positioned between a fluorosphore and a nucleotide of a tracer compound; wherein the linker may include an aminoallyl, a diaminoalkane, or an aminoalkynyl group.

In another aspect, the invention provides a composition, preferably EGTA, for use in a homogenous competitive binding assay to stabilize an assay signal by preventing breakdown of a donor product.

In another aspect, the invention provides a composition, preferably sodium vandate, for use in a homogenous competitive binding assay to quench a group transfer reaction.

Other advantages and a fuller appreciation of specific adaptations, compositional variations, and physical attributes will be gained upon an examination of the following detailed description of the various embodiments, taken in conjunction with the appended claims.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 illustrates a fluorescence polarization immunoassay (FPIA) reaction for the SULT reaction product, PAP.

FIG. 2 illustrates use of FPIA to detect and quantify UDP formation, the donor product of the UGT reaction.

FIG. 3 illustrates use of FPIA to detect and quantify ADP formation, the donor product of the kinase reaction.

FIGS. 4A-B depict examples of suitable tracers used to quantify UDP formation.

FIG. 5 shows titration or competitive displacement curves for uridine nucleotides using a polyclonal antibody raised against UDP/UTP and a commercially available tracer molecule (Alexa-UTP).

FIG. 6 shows standard UGT reaction conditions for detection of enzymatically generated UDP by competitive FPIA.

FIG. 7 shows the dependence of the FPIA-based UGT enzymatic assay on enzyme concentration and time.

FIG. 8 shows the dependence of the FPIA-based UGT enzymatic assay on acceptor concentration.

FIG. 9 shows use of the competitive FPIA for detection of UDP formation by diverse UGT isoforms and acceptor substrates.

FIGS. 10A-B show competitive displacement of two different Alexa Fluor-UTP tracers from antibody by UDP and UDPGA.

FIG. 11 shows the effect of stabilizing reagents on the FPIA signal in UGT reactions.

FIG. 12 shows FP competition curves for ADP, ATP and AMP using a polyclonal antibody against ADP and a 5-FAM-N6-ADP tracer.

FIG. 13 shows synthesis of a 5-FAM-N6-ADP tracer.

FIG. 14 shows examples of tracers used to quantify ADP formation.

FIG. 15 shows the dependence of the FPIA-based kinase enzymatic assay on enzyme concentration and time.

FIG. 16 shows the synthesis of PAP antigens.

FIGS. 17A-C show components of PAP tracer synthesis.

FIGS. 18A-C show representative final PAP tracer structures.

FIG. 19 shows binding isotherms for anti-PAP antibodies and PAP-fluorescein tracers.

FIG. 20 shows competitive displacement of two different tracers from Ab 3642 by PAP and PAPS.

FIGS. 21A-B show the competition curves with two Anti-PAP antibody/Tracer combinations.

FIG. 22 shows the effect of PAPS concentration on detection of enzymatically generated PAP.

FIGS. 23A-F show a continuous FPIA-based detection of SULT activity with diverse substrates.

FIG. 24 shows a comparison of SULT1E1 acceptor substrate profiles determined using the FPIA-based assay and the ³⁵S-PAPS radioassay.

FIG. 25 shows inhibition of SULT1E1 by 2,6 Dichloro-4-nitrophenol (DCNP) measured with the FPIA-based assay.

Before the various embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details set forth in the following description. The invention is capable of being practiced or being carried out in a variety of ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting in any way.

DETAILED DESCRIPTION OF THE INVENTION

The present invention broadly relates to novel assay methods for detecting and quantifying the donor-product or the catalytic activities generating the donor-product from group transfer enzymes using diverse substrates. The invention also provides the antibodies specific to the donor product and assay kits for practicing the invention in a high-throughput screening format. The general equation for the group transfer reaction includes a donor-X+acceptor→donor-product+acceptor-X, wherein the donor-product is detected by the general detection reaction: first complex+donor-product→second complex+displaced detectable tag. Thus, in accordance with the invention, a highly selective antibody is used to bind the donor product of the group transfer reaction, and this binding event is detected, using an immunoassay, such as for example a competitive binding FPIA which is well suited for pharmaceutical HTS assays. By using this detection mode, enzymatically generated donor product displaces a tracer, from an antibody resulting in a decrease in tracer fluorescence polarization. The key reagents for the assay are antibody that binds with high selectivity to the donor product, and not to the uncleaved donor molecule, and a tracer—a fluorescent derivative of the donor product that retains its structure sufficiently to bind the antibody.

In particular the invention provides a universal assay method in that a single set of detection reagents can be used for all of the enzymes in a given family of group transfer enzymes and all acceptor substrates for that family. This universal assay method provides a novel approach for accelerating the incorporation of SULTs, protein kinases and other group transfer enzymes into HTS screening.

As an illustration of the universal nature of the invention, the novel assay method would allow SULT isoforms (i.e., there are eleven known SULT isoforms) to be screened for their ability to sulfate diverse compounds in the same experiment using the same detection reagents, protocol and instrumentation. This is an important capability because enzymes that catalyze xenobiotic conjugation (e.g., SULTs and UGTs) have very broad acceptor substrate specificity. With respect to kinases, there is even more diversity within the enzyme family. There are over 400 protein kinases in humans, and there is great diversity in their acceptors substrate specificity such that either physiological protein acceptor substrates as well as short peptides may be used. As such, a number of protein kinases may be used in the assay of the invention using their diverse acceptor substrates and screened for inhibitors using the same detection reagents, protocol and instrumentation. For these reasons and others provided below, the FPIA based donor product detection assays of the invention for group transfer reactions such as SULT, UGT and kinases, among others are very well suited for automated HTS applications.

Accordingly, the present invention will now be described in detail with respect to such endeavors; however, those skilled in the art will appreciate that such a description of the invention is meant to be exemplary only and should not be viewed as being limiting on the full scope thereof.

Definitions

Certain terms used herein are intended to have the following general definitions:

The term “group transfer reaction” as used herein refers to the general reaction:

-   -   donor-X+acceptor→donor-product+acceptor-X.

Representative group transfer reactions are shown as follows:

-   Kinase reaction: ATP+acceptor→ADP+acceptor-PO₄; -   UGT reaction: UDP-glucuronic acid+acceptor→UDP+acceptor-glucuronic     acid; -   SULT reaction: acceptor-XH+3′-phosphoadenosine     5′-phosphosulfate→acceptor-SO₄+3′-phosphoadenosine 5′-phosphate+H⁺; -   Methyltransferase reaction:     s-adenosylmethionine+acceptor→acceptor-CH₃+s-adenosylhomocysteine;     and -   Acetyl transferase reaction: acetyl     CoenzymeA+acceptor→acceptor-COCH₃+CoenzymeA.

Group transfer reactions in-part such as sulfation by SULTs, phosphorylation by kinases and UDP-glucuronidation by UGTs are suitably applicable to the methods of the invention because one can isolate antibody/detectable tag pairs for the donor products, which are PAP, ADP and UDP, respectively. Also group transfer reactions are generally involved in a number of biological processes, such as hormone biosynthesis and function; enzyme regulation and function; and xenobiotic metabolism.

The term “universal assay” and “generic assay” are used interchangeably to refer to a method whereby all members of the group transfer reaction enzyme family and all of their acceptor substrates can be detected with the same assay reagents.

The term “group” in group transfer reaction refers to the covalent adduct or the moiety that is being transferred from the donor molecule to the acceptor in a group transfer reaction. Groups transferred in enzymatically catalyzed group transfer reactions typically include phosphates, sulfates, carbohydrates, naturally occurring amino acids, synthetically derived amino acids, methyls, acetyls, glutathione moieties, and combination thereof.

The term “covalent adduct” refers to the moiety that is transferred from the donor molecule to the acceptor in a group transfer reaction; such as sulfonate, phosphate, and glucuronic acid respectively for SULTs, kinases, and UGTs.

The term “donor-product” as used herein refers to the product of a group transfer reaction that is the fragment of the donor molecule that is generated when the covalent adduct is transferred to acceptor. Often it is a nucleotide (naturally occurring or synthetic) such as a PAP, UDP or ADP; or a non-nucleotide such as a s-adenosylhomocysteine, nicotinamide or a CoenzymeA. The donor-product is detected by a general reaction including a first complex+donor-product→second complex+displaced detectable tag.

The term “tracer” as used herein refers to a displaced detectable derivative or tag of a donor product that retains its structure sufficiently to bind to a specific antibody.

The term “donor” as used herein refers to a substrate for an enzyme catalyzing a group transfer reaction that carries the activated covalent adduct. Examples of suitable donors include not only nucleotides, but also s-adenosyl methionine and acetyl-CoA, among others.

The term “donor-X” is another term for donor molecule in which X represents the covalent adduct.

The term “acceptor” as used herein refers to a substrate for an enzyme catalyzing a group transfer reaction to which the covalent adduct becomes covalently attached, wherein the substrate is a polypeptide, a protein, a nucleic acid, a carbohydrate, a lipid or a small molecule substrate such as a steroid or an amino acid.

The term “acceptor-X” as used herein refers to a reaction product in which X is the covalently bound covalent adduct; wherein the covalent adduct includes at least one of a phosphate, a sulfate, a carbohydrate, a naturally occurring amino acid, a synthetically derived amino acid, a methyl, an acetyl, or a glutathione moiety, and a combination thereof. The covalent adduct is capable of altering either the function, the stability, or both the function and the stability of the acceptor substrate.

The term “catalytically active enzyme” as used herein refers to at least one of a sulfotransferase, a kinase, a UDP-glucuronosyltransferase, a methyl transferase, an acetyl transferase, a glutathione transferase, or a ADP-ribosyltransferase.

The term “catalytic activity” as used herein refers to a chemical catalytic activity, an enzymatic activity, or a combination thereof.

The term “first complex” as used herein refers to a complex having a macromolecule (i.e., an antibody or an inactivated enzyme) and a detectable tag.

The term “second complex” as used herein refers to a macromolecule and the donor product wherein the detectable tag is competitively displaced by the donor-product.

The term “observable” as used herein refers to detectable change in fluorescence, fluorescence intensity, fluorescence lifetime, fluorescence polarization, fluorescence resonance energy transfer (FRET) or chemiluminescence of the second complex or the displaced detectable tag and a combination thereof to obtain a measured observable. The measured observable is compared with a characterized observable, wherein the characterized observable corresponds to the first complex.

The term “detectable tag” as used herein refers to a fluorescent or chemiluminescent tracer, which is conjugated to a donor product. Fluorescence is the preferred mode of detection for the invention. A suitable detectable tag may be produced by conjugating for example, a chemiluminescent tag or a fluorophore tag, to the donor product molecule in such a way that it does not interfere significantly with antibody binding (i.e., most likely attached via the base portion of the nucleotide). Fluorophores applicable to the methods of the present invention include but are not limited to fluorescein, rhodamine, BODIPY, Texas Red, Alexa Fluors and derivative thereof known in the art. Rhodamine conjugates and other red conjugates may be synthesized and optimized as detectable tags because their higher wavelength emission is less subject to interference from autofluorescence than the green of fluorescein.

Chemiluminescent tags applicable to the invention include Lumigen TMA-6 and Lumigen PS-3 (Lumigen, Inc., Southfield, Mich.) which have adequate chemiluminescence quantum yield. These reagents possess an easily measured signal by virtue of an efficient chemiluminescent reaction with a predictable time course of light emission. Furthermore, chemiluminescent tags contribute little or no native background chemiluminescence. Also, measurement of light intensity is relatively simple, requiring only a photomultiplier or photodiode and the associated electronics to convert and record signals. In addition, chemiluminescent signals can be generated in an immunoassay using enzyme fragment complementation methods, where the detectable tag would be the donor product conjugated to fragment A of a reporter enzyme, and its displacement from antibody by the donor product generated in the group transfer reaction would allow it to associate with fragment B of the enzyme resulting in formation of a catalytically active reporter enzyme capable of acting on a chemiluminescent substrate. This method has been described using β-galactosidase as a reporter enzyme in U.S. Pat. No. 4,708,929.

The term “immunoassay” as used herein may refer to a number of assay methods wherein the product is detected by an antibody such as for example a homogenous assay, homogeneous fluorescence immunoassay, a homogeneous fluorescence intensity immunoassay, a homogeneous fluorescence lifetime immunoassay, a homogeneous fluorescence polarization immunoassay (FPIA), a homogeneous fluorescence resonance energy transfer (FRET) immunoassay or a homogenous chemiluminescent immunoassay, or a non-homogenous assay such as enzyme-linked immunoassay (ELISA) and a combination thereof.

The term “fluorescence polarization immunoassay” or “FPIA” as used herein refers to an immunoassay for detecting the products of group transfer reactions. Fluorescence polarization (FP) is used to study molecular interactions by monitoring changes in the apparent size of fluorescently-labeled or inherently fluorescent molecules (Checovich, W. J., et al., Nature, 1995, 375:254-6; Owicki, J. C., J Biomol Screen, 2000, 5:297-306). When a small fluorescent molecule (tracer) is excited with plane polarized light, the emitted light is largely depolarized because the molecule rotates rapidly in solution during the fluorescence event (the time between excitation and emission). However, if the tracer is bound to a much larger receptor, thereby increasing its effective molecular volume, its rotation is slowed sufficiently to emit light in the same plane in which it was excited. The bound and free states of the fluorescent molecule each have an intrinsic polarization value, a high value for the bound state and a low value for the free state. In a population of molecules, the measured polarization is a weighted average of the two values, thus providing a direct measure of the fraction of the tracer molecule that is bound. Polarization values are expressed as millipolarization units (mP), with 500 mP being the maximum theoretical value.

In practice, small molecules like fluorescein have polarization values of approximately 20 mP, and when bound by an antibody their polarization increases by 100 to 400 mP. In a competitive FPIA, a fluorescent tracer may be displaced from binding to antibody by the donor product, as shown in FIG. 1. The signal is proportional to the difference in the bound versus free tracer fractions, thus both the dynamic range and the sensitivity of the assay are dependent upon the affinity of the antibody for the tracer and the donor product. To establish a suitable dynamic range for an FPIA, approximately 70-80% of the tracer must be bound to antibody in the absence of competitor.

For example, FIG. 1 shows a schematic of a competitive FPIA for the SULT reaction product PAP in which the PAP produced from the SULT reaction competes with the tracer (fluorescently tagged PAP), for binding to anti-PAP antibody. In this format, the starting polarization of the tracer is high because it is almost all bound to antibody, and it decreases as the reaction proceeds and the tracer is displaced from the antibody. The amount of PAP produced in a SULT reaction can be quantified by using the following equation:

${\log\mspace{14mu}\left\lbrack {{PAP}\mspace{14mu}{product}} \right\rbrack} = {{\log\frac{\left( {{{highest}\mspace{14mu}{polarization}} - {mP}_{observed}} \right)}{\left( {{mP}_{observed} - {{lowest}\mspace{14mu}{polarization}}} \right)}} + \mspace{225mu}{\log\mspace{14mu}{{IC}_{50}.}}}$

In the enzymatic assay encompassed by the present invention, the PAP for SULTs or ADP for kinases is produced in stoichiometric amounts with the sulfated product or phosphorylated peptide, respectively. Thus the use of a standard curve for PAP or ADP among other donor products will allow a direct measure of enzyme turnover.

The term “high throughput screening” or “HTS” as used herein refers to the testing of many thousands of molecules (or test compounds) for their effects on the function of a protein. In the case of group transfer reaction enzymes many molecules may be tested for effects on their catalytic activity. HTS methods are known in the art and they are generally performed in multiwell plates with automated liquid handling and detection equipment; however it is envisioned that the methods of the invention may be practiced on a microarray or in a microfluidic system.

The term “library” or “drug library” as used herein refers to a plurality of chemical molecules (test compounds), a plurality of nucleic acids, a plurality of peptides, or a plurality of proteins, and a combination thereof. Wherein the screening is performed by a high-throughput screening technique, wherein the technique utilizes a multiwell plate or a microfluidic system.

The terms “binding molecule” or “macromolecule” as used herein refers to an antibody or an inactivated enzyme.

The term “antibody” as used herein refers to a monoclonal, a polyclonal or recombinant antibody. The antibody is produced against a donor-product of a group transfer reaction and is able to preferentially distinguish between a donor-product and a donor in the presence of a high donor concentration. The antibody also exhibits specificity towards at least one of a phosphate portion of a nucleotide, (i.e., an ability to distinguish between a 5′-phosphate, a 5′-phosphosulfate, a 5′-diphosphate and a 5′-triphosphate). For example, in the SULT reaction, the antibody of the present invention differentiates with high stringency between PAP and PAPS. The donor-product molecule for the SULT reaction, PAPS, differs only by the addition of a sulfate group linked to the 5′ terminal phosphate. This may seem like a relatively small structural difference, but the demonstrated ability of antibodies to discriminate between molecules that differ by a single phosphate—which is very similar in size and structure to a sulfate group—provides an important feature of the present invention. For example, an antibody may be raised against the ribosyl phosphate portion of the molecule. Furthermore, the FPIA-based SULT assay method of the present invention suitably requires an antibody that specifically binds the reaction product PAP in the presence of excess PAPS.

In practicing the invention with respect to kinases, antibodies that specifically recognize ADP and not ATP may be generated in animals or by in vitro recombinant methods using ADP conjugated to a carrier protein in such a way that the phospho-ribosyl portion of the molecule is exposed, but the adenine portion is largely hidden from immunoreactivity. In generating antibodies, it may be helpful to use a nonhydrolyzable analog of ADP, such as one containing a methylene or sulfur group bridging the alpha and beta phosphates in order to prevent hydrolysis of the immobilized hapten by nucleotidases or phosphatases in the immunized animals. Alternatively, with respect to methyltransferases and acetyltransferases, antibodies that specifically recognize small molecules other than nucleotides, respectively s-adenosyl homocysteine and Coenzyme A are used.

The term “inactivated enzyme” as used herein refers to a binding molecule that may bind to the donor product. In the case of a kinase, the ADP is the donor product and an inactivated nucleoside diphosphate (NDP) kinase may be the binding molecule. It is known that in many enzymes, separate domains are involved in binding and in catalysis. A selective destruction of the catalytic activity with preservation of the binding properties by genetic engineering, allosteric inhibition, or other chemical means such as taking out cofactors, heme groups, etc. may enable enzymes, particularly multi-subunit enzymes to function as specific carriers for their substrates that are no longer able to chemically modify these substrates.

The term “antibody-detectable tag pair” as used herein refers to an anti-donor product antibody and detectable tag (fluorescent-donor product) molecule that allow detection of donor product produced in a group transfer reaction. A suitable dissociation constant for binding of the antibody/detectable tag pair is 1×10⁻⁵M or lower, resulting in a minimal fluorescence polarization shift of 50 mP relative to the unbound detectable tag, and with minimal cross reactivity to the donor molecule at reaction concentrations. The optimal antibody-detectable tag pair may be identified by testing a number of different antibodies generated using different sites of attachment to the donor molecule, different linkers to the carrier protein, and including some non-hydrolyzable analogs for interaction with a set of detectable tags generated by varying the chemistry of donor molecule attachment to a fluorophore. The changes in fluorescence or chemiluminescence of the detectable tag upon interaction with an antibody that could have a fluorophore for example attached t it; may be used as a measure of their interaction.

The term “linker” as used herein refers to spacer arm structures that join the donor product to the carrier protein in the immunogen or to the fluorophore in the detectable tag. There are short linkers (i.e., carbamoyl and aminoethyl groups) that will sterically minimize the accessibility of the adenine ring and longer six carbon linkers that will allow more flexible presentation of the antigen. The linker molecule affects detectable tag characteristics in a number of important ways that impact both its antigenic and fluorescence properties. There is generally a balance that must be struck between separating the antigen from the fluorophore enough to allow unhindered interaction with antibody without creating too much freedom of motion for the fluorophore. The former result in lowered affinity antibody binding and in quenching of the fluorophore, whereas the latter reduces the polarization shift upon antibody binding, thereby reducing the dynamic range of the assay. Different linkers can be interchanged using relatively simple chemistry, thus the linker is varied in a number of ways in efforts to optimize the antigenic and fluorescence properties of the detectable tag. Furthermore, approaches may be employed similar to those described for PAP conjugation of an antibody involving heterobifunctional linkers to first introduce spacer arms and/or aromatic substituents onto PAP, followed by reaction with reactive fluorescein derivatives. This approach greatly expands the range of possible linker structures.

Methods and Materials

The following experimental protocols of the invention are not limited to the particular methodology, protocols, antibodies, enzymes, detectable tags, among other reagents described, as these may vary depending on the group transfer reaction. It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments only, and is not intended to limit the scope of the present invention.

Development of Assay Reagents

In developing a successful HTS assay format for the invention the affinity and specificity of the antibody-detectable tag pair, and the resultant changes in detectable tag fluorescence properties ultimately define the overall performance of the assay, including sensitivity, dynamic range, and signal to noise ratios. As such, to optimize this interaction, applicants have provided an iterative co-development strategy for these key assay reagents.

This co-development strategy provides that several different antibodies be tested to identify one that specifically binds the donor product in the presence of excess donor molecule. For the immunogen used to generate antibody, the donor molecule may be conjugated to carrier protein (e.g., BSA or KLH) via attachment through different positions using linker molecules of varying lengths with reactive termini; e.g. amino groups. The same donor-linker reactive intermediates used for carrier protein conjugation may be used to synthesize fluorescein-PAP conjugates to test as detectable tags. The resulting matrix of antibodies and detectable tags may be tested for binding using FP assays, and the pairs that exhibit high affinity binding and maximal FP shifts may be used as the basis for further optimization of tracer characteristics. Optimized antibody-detectable tag pairs may be tested for detection of donor molecule production in enzymatic reactions.

Also, it is envisioned that several donor molecule antigens and detectable tags may be synthesized by conjugating the donor molecule to carrier protein and fluorescein, while retaining an overall structural bias that maximizes antibody recognition of the part of the molecule that differs from the donor so that crossreactivity with the donor is minimized. For a nucleotide donor products, this generally means attaching the linker to the base portion of the nucleotide so that the ribosyl-phosphate moiety is unaltered and fully exposed. For example, in the case of adenine nucleotide donor product, it is known in the art that conjugation to adenine will minimize antibody cross reactivity that could occur via binding to the adenine moiety (Goujon, L., et al., J. Immunol Methods, 1998, 218:19-30; Horton, J. K., et al, J Immunol Methods, 1992, 155:31-40; Bredehorst, R., et al., Biochim Biophys Acta, 1981, 652:16-28). The site of hapten conjugation also can affect the affinity of the resulting antibodies (Crabbe, P., et al., J Agric Food Chem, 2000, 48:3633-8). With some larger donor products, such as Coenzyme A, it may be desirable to use only a portion of the molecule as antigen so that crossreactivity with the structural elements shared with the donor are minimized.

Generation of High Affinity, High Selectivity Antibodies

In accordance with methods of the present invention, one skilled in the art may readily prepare a variety of specific antibodies (i.e., polyclonal, monoclonal or recombinant) against donor molecules bound to carrier proteins.

In general polyclonal antibodies against a range of donor product antigens are suitably generated in rabbits. It is difficult to predict how the structure of the antigen will affect the affinity and selectivity of the resulting antibodies, but the carrier protein and mode of conjugation both can have a profound effect (Crabbe, P., et al., J Agric Food Chem, 2000, 48:3633-8; Signorini, N., et al., Chem Res Toxicol, 1998, 11:1169-75; Oda, M. and Azuma, T., Mol Immunol, 2000, 37:1111-22). Accordingly, antibodies may be generated using conjugation to two different proteins via different sites on the donor product and using different length linker regions.

The injection of animals and collection of serum may be performed according to the following protocol. Three rabbits may be immunized with each of the antigens that may be developed. The yields of antiserum from a single rabbit (˜100 ml) are suitable for many thousand to millions of FPIA assays depending on the titer, affinity, and the multivalent nature of polyclonal-antigen interactions resulting in very high affinity binding. As such, for these reasons polyclonals are frequently used for FPIAs (Nasir, M. S. and Jolley, M. E., Comb Chem High Throughput Screen, 1999, 2:177-90).

Also, encompassed within the scope of the present invention are monoclonal antibodies which may be produced according to the methods provided in previously published protocols (Harlow, E. L., D., 1999), which are fully incorporated herein by reference. Although mice are widely used for generation of monoclonal antibodies, rabbit hybridoma technology has also recently become available. Rabbits are believed to be more effective than mice for generation of high selectivity antibodies against small haptens, thus rabbit monoclonal antibodies may prove to be a better approach for generating the high selectivity and affinity desired for this application. Also, recombinant single chain antibodies, may be generated using the in vitro combinatorial evolution and display methods previously published (Schaffitzel, C., et al., J Immunol Methods, 1999, 231:119-35; Breitling, F., Dubel, S., 1999). Examples of the preparation of recombinant antibodies are described in U.S. Pat. Nos. 5,693,780; 5,658,570; 5,876,961 (fully incorporated by reference herein).

In order to help elicit an immune response, bovine serum albumin (BSA) and keyhole limpet hemocyanin (KLH) may be used as carrier proteins for conjugation of the PAP antigen. KLH antigens generally elicit a stronger immune response in mammals, but also tend to be less soluble than BSA conjugates (Harlow, E. L., D., 1999). Donor products with an adenine ring such as ADP and PAP may be attached to both carrier proteins via the C2, C8 and N6 amino group of adenine. Donor products with a uridine ring can be conjugated via the C5 or C6 position of uridine. Either type of nucleotide may be conjugated through the ribose 2′ and 3′ hydorxyls.

Conjugation Methods

The hapten conjugation chemistries used by the invention are well described single or two step synthetic approaches that have been used extensively for conjugating nucleotides for generation of immunogens or for immobilizing them on solid supports (Brodelius, P., et al., Eur J Biochem, 1974, 47:81-9; Lindberg, M. and Mosbach, K., Eur J Biochem, 1975, 53:481-6; Camaioni, E., et al., J Med Chem, 1998, 41:183-90). Most of the starting materials are commercially available, or can be obtained through custom synthesis, and it is understood that the reactions may proceed in good yield. These conjugation methods are described in the Examples in further detail. It is envisioned that the present invention may encompass but may not be limited by the hapten conjugation chemistries described herein. It is also envisioned that about 8-10 different antigens may be synthesized in all. Some antigens will have very short linkers such as C2 or C3 that will sterically minimize the accessibility of the base and others will have longer six carbon linkers that will allow more flexible presentation of the antigen.

Synthesis and Purification of Detectable Tags

In general, an FPIA detectable tag molecule can be divided into three different structural components: the antigen, the fluorophore, and the linker used to join them; an additional key structural variable is the site of attachment of the linker to the antigen. It is understood by one skilled in the art that suitable antigens, fluorophores and linkers are not limited to what is specifically described herein. However, in a suitable aspect of this invention, the same donor product-linker molecules that are used for conjugation to carrier proteins may be used for conjugation to several reactive fluorophore derivatives. The use of a range of reactive fluorophores may introduce additional structural diversity in the linker region. For instance, fluorescein succinimidyl esters are available with different length spacer arms, and DTAF (4,6-Dichlorotriazinylaminofluorescein) contains a bulky planar substituent adjacent to the site of attachment. Briefly, various donor product-linker molecules with reactive termini such as amino groups may be reacted with amine-reactive fluorophore derivatives and the resulting donor product-fluorophore conjugates may be tested for antibody binding affinity and changes in fluorescence polarization.

Purification of detectable tags can be performed by thin layer chromatography (TLC). TLC is used to separate reaction products because it allows several separations to be run in parallel, permits identification of fluorescent products by visualization and, provides sufficient quantities of fluorescent conjugates for thousands of binding assays in a single chromatography run. Thus, for pilot studies on fluorescent detectable tag molecules, TLC is superior to alternative separation methods like HPLC. Upon completion of the chromatography and elution of the donor product-fluorophore conjugates, the conjugates may be analyzed for intensity, basal polarization (absence of antibody), stability, binding to antibodies, and competition by unlabeled donor product and donor molecule, as described below.

Parameters Affecting the Antibody-detectable Tag Interaction

In order to create the most sensitive assay method for detecting, quantifying, and screening products of group transfer methods, the parameters affecting the affinity of the antibody-detectable tag interactions is carefully monitored. Often, the cost of the enzyme is the limiting factor in an HTS assay. In general, it is desirable to have an antibody capable of detecting donor product at a concentration of 1 μM or lower. This allows the use of relatively small amounts of enzyme to produce a detectable amount of donor product within a practical time period of 0.5 to 4 hours.

Most antibody-antigen interactions with either polyclonal or monoclonal antibodies have a K_(d) between 1 nM and 1 μM (Harlow, E. L., D., 1999), which is suitable for the above enzymatic detection parameters. The kinetics of the antibody-detectable tag interaction is a secondary consideration. If the donor product can displace the detectable tag rapidly enough, the FPIA can be used to monitor enzyme activity continuously in real time. This can be advantageous for some applications such as detailed kinetic studies. Also, obtaining screening data that includes time dependence can help to eliminate false positives resulting from autofluorescent compounds.

Furthermore, the difference in polarization of the probe in the free and bound states defines the total “spread” or dynamic range for the assay. A change of less than 50 mP may be sufficient for semi-quantitative detection of enzyme activity, but a change of 100 mP or greater may provide both much greater flexibility in designing the assay format, and more quantitative kinetic information. (It should be noted that improvements in instrumentation may soon make it possible to accurately detect very small changes in polarization.) Accordingly, polarization is proportional to molecular volume, and the change in effective volume upon binding of an antibody (150 kDa) to a small molecular weight fluorophore may be expected to cause an increase of at least 300 mP. However, there are other factors that can affect the observed polarization of both the free and bound detectable tag, such as, the fluorophore is attached to PAP by a flexible spacer arm. Thus, their maximum polarization is a function of the extent to which antibody binding decreases the mobility of the spacer and fluorophore; detectable tag “propeller effects” can lead to relatively low polarization values even for protein-bound fluorophores.

An additional consideration is whether there may be changes in the intensity of the fluorophores upon binding to receptor, including quenching from amino acid functional groups with overlapping spectra. Polarization is independent of fluorescence intensity (Owicki, J. C., J Biomol Screen, 2000, 5:297-306); however, because it is a ratio of intensity measurements taken in two planes, significant quenching may affect the antibody detectable tag interaction and result in decreased assay sensitivity. The changes in the fluorescence properties of a detectable tag when it becomes bound by antibody are a function of both interacting molecules and are difficult to predict. Thus, it is envisioned that different antibodies and detectable tag molecules will be tested in a matrix fashion. Further optimization of the detectable tag structure or the assay buffer to limit mobility of the bound detectable tag or to reduce quenching is also envisioned.

Identification of the Optimal Antibody/Detectable Tag Pair(s)

In order to identify optimal antibody/detectable tag pairs, a diverse set of fluorescent derivatives and linkage chemistries are generally evaluated. The synthesis and purification methods described above result in the isolation of several fluorescent products per reaction, so that at least a hundred fluorescent conjugates may be evaluated, requiring thousands of individual FP assays. The homogenous nature of FP assays and the availability of multiwell instruments makes the screening efforts very rapid; the rate-limiting steps are usually synthesis and purification, not testing for antibody-detectable tag binding properties. The antibody/detectable tag testing may be carried out in a Tecan Ultra multiwell FP reader in Tris or phosphate buffer in the presence of a low concentration of carrier protein (0.01% Bovine Gamma Globulin) to prevent non-specific interactions. The initial screen involves looking for the following desirable properties: low polarization in the absence of antibody (<100 mP); high affinity binding to the anti-donor product antibodies (K_(d)<1 μM); maximal difference in polarization between the bound and free states (Δ mP>100 mP); minimal fluorescence quenching upon binding antibody; selectivity for donor product (i.e., competitive displacement by donor product and not by donor molecule; rapid association/dissociation kinetics; and lack of interaction with other assay components.

APPLICABILITY OF THE INVENTION

The methods of the invention, as described in the examples below can be used as a measure of enzymatic activity in group transfer reactions. The methods are of particular importance in the pharmaceutical industry since they enable the analysis of group transfer enzymes in high throughput screening laboratories, e.g. for identification of drugs that can act as enzymatic modulators, especially inhibitors, and for determining how potential drug molecules are metabolized.

There is an increasing number of group transfer enzymes that are being targeted for the development of new therapeutics. Kinases are currently of highest interest, but SULTs, UGTs, methyltransferases, acetyltransferases, and ADP-ribosyltransferases are also being targeted. As this list increases it will become impractical and extremely expensive to use specific tests for each enzyme, or for small subgroups of enzymes that modify the same acceptor substrate. The assays and kits of the present invention allow for the detection of all of the enzymes in a given group transfer enzyme family and provide a common end point detection system for all of them. This allows for greater ease of use, particularly in high throughput screening laboratories, where robots can be set up with all the detection reagents and the various group transfer enzymes and potential substrates or inhibitors of interest can be tested in a matrix fashion.

In addition, the involvement of group transfer reactions in the conjugative metabolism of drugs and other xenobiotics is an important determinant in their pharmacodynamics, pharmacokinetics and side effects. In this regard, the assays and kits of the present invention allow for the screening of potential drug molecules with SULTs, UGTs, methyltransferases and acetyltransferases in an HTS format. There are many different xenobiotic conjugating isoforms, and because of the generic nature of the method, the kits of the present invention would greatly simplify their testing in a matrix fashion.

Thus, the general methods of the invention may be applied to a variety of different group transfer-related enzymatic processes, such as steroid hormone biosynthesis and function, xenobiotic metabolism, enzyme receptor regulation, and signal transduction in an effort to contribute to an integrated drug discovery approach discussed below.

Sulfation in Drug Discovery

Sulfation is a ubiquitous cellular conjugative reaction used to modulate the function of endogenous biomolecules including proteins, carbohydrates, and small molecular weight signaling molecules like catecholamines and steroid hormones (Strott, C. A. (2002) Endocr Rev 23, 703-732). Sulfotransferase enzymes catalyze the conjugation of sulfonate groups onto a variety of xenobiotic and endogenous substrates primarily at hydroxyl groups to form a sulfate, but also at some aromatic amines resulting in sulfamate formation. Sulfotransferase reaction: R—XH+3′-phosphoadenosine 5′-phosphosulfate→R—SO₄+3′-phosphoadenosine 5′-phosphate+H⁺ (It is noted that the reaction catalyzed by SULTs is formally a “sulfonation” not a “sulfation” reaction, but historically sulfation is the term that has been used because the conjugates formed are sulfates.)

3′-phosphoadenosine 5′-phosphosulphate (PAPS) serves as the donor molecule for the activated sulfate, the product after sulfate transfer is the 3′,5′-bisphosphate adenine ribonucleotide, known as phosphoadenosine phosphate (PAP); this is the molecule that is detected in the FPIA described herein. There are two major classes of SULTs in humans that differ in solubility, size, subcellular distribution, and share less than 20% sequence homology. The membrane bound enzymes are located in the golgi apparatus and sulfonate large endogenous molecules such as heparan, glycosaminoglycans, and protein tyrosines. The cytosolic sulfotransferases, or SULTs, metabolize small molecular weight xenobiotics and hormones.

Sulfation is reversible and can change the activity of signaling molecules, often by altering their affinity for receptor proteins, thus it serves as an on-off switch for receptor ligands, much as phosphorylation serves that role for proteins. Moreover, the role of sulfation in xenobiotic metabolism is intertwined with its involvement in the regulation of hormonal signaling and cell homeostasis. For instance, sulfation regulates the activity of endogenous ligands for specific neurotransmitter receptors, nuclear receptors, and protein kinases that are drug targets for depression, breast cancer, and cardiovascular disease (Plassart-Schiess, E. and Baulieu, E. E., Brain Res Brain Res Rev, 2001, 37:133-40; Strott, C. A., Endocr Rev, 1996, 17:670-97; Kuroki, T., et al., Mutat Res, 2000, 462:189-95). Development of more selective therapies for these disorders by pharmaceutical companies is currently hampered by a lack of molecular assays and purified SULT isoforms for high throughput screening (HTS) of potential SULT substrates and inhibitors.

There are eleven known cytosolic SULT isoforms, which differ in their tissue distribution and specificity. The nomenclature used is based on homology at the amino acid level: SULTs within the same family, indicated by a number, share at least 45% amino acid identity, and those within the same subfamily, designated by a letter, share at least 60% identity. The SULTs can be differentiated to some degree based on substrate specificity, though their substrate profiles overlap extensively, even between enzymes in the different families.

It is envisioned that the assays of the invention may be used in an HTS format to provide for example, SULT metabolism information such as whether the compound of interest interacts with one or more SULT isoforms, whether the compound is a substrate or inhibitor, and the kinetic parameters (IC₅₀, K_(m), V_(max)) for the interaction. The HTS assay encompassed by the present invention provides all of this information by screening in two different modes: a) direct measurement of test compound turnover; and b) measurement of compound inhibition of probe substrate sulfation. In the direct turnover mode, compounds could be screened vs. a panel of SULT isoforms to profile compound sulfation by individual SULT isozymes. After isozyme identification, more detailed kinetic studies with the appropriate SULT isozyme could be used to predict in vivo clearance rates (Obach, R. S., et al., J Pharmacol Exp Ther, 1997, 283:46-58), reducing the failure rate of compounds in clinical studies (Greco, G. N., E; Martin, Y C, 1998, 219-245). SULT inhibitors could be identified by using a known substrate—e.g. estradiol for SULT1E1—and screening test compounds for inhibition. Isozyme specific kinetic and inhibition data will further improve drug discovery by providing knowledge of metabolism by specific SULT alerting the drug discovery team to potential drug-drug interactions and pharmacogenetic issues. The contribution of genetic differences in SULTs to varying responses to therapeutics is an active area of investigation (Thomae, B. A., et al., Pharmacogenomics J, 2002, 2:48-56).

Identification of the SULT responsible for the metabolism of a drug will aid in judicious selection of the in vitro assays or animal models used for preclinical assessment of possible drug-drug interactions and toxicology testing, thereby reducing inappropriate or unnecessary experimental animals use. Metabolism data can be used as a component of rational drug design and lead optimization. A better understanding of the structure-activity relationships that define substrate specificity for the various SULT isozymes may provide a basis for structural modifications of primary compounds to change their metabolism profile (Greco, G. N., E; Martin, Y C, 1998, 219-245). Accordingly, the methods of the present invention will enable a better understanding of the structure-activity relationships that define substrate specificity for the various SULT isozymes.

Integrated Approach to Drug Discovery

The ability of the assays of the invention to be used as HTS assays enables a rational, integrated approach to drug development for therapeutic areas where for example, sulfation is a component of the relevant signal transduction biology. Some specific areas where the HTS methods of the invention may be used include for example steroid hormone based therapies. Sulfation, in accordance with the present invention, encompasses involvement in estrogen level regulation in mammary tumors, as well as androgen levels in prostate tumors. Furthermore, cortisol sulfation, though not well understood, inactivates the hormone for binding to the glucocorticoid receptor. High throughput biochemical assays for steroid ligand-receptor binding and the resultant binding of transcriptional coregulator proteins are already commercially available and being used by pharma HTS groups to find more selective steroid hormone modulators (Parker, G. J., et al., J Biomol Screen, 2000, 5:77-88; Spencer, T. A., et al., J Med Chem, 2001, 44:886-97). As such, the availability of robust HTS assays for steroid sulfation may provide an important addition to the arsenal of molecular tools available to pharma groups focused on steroid signal transduction. For instance, the inhibition of SULT1E1 by drugs targeting the ER for the treatment of breast cancer could cause deleterious effects by elevating estrogen levels in tumor cells. Molecules with SULT1E1 inhibitory properties could be culled or modified based on studies using the assay methods of the present invention.

The modulation of neurosteroids is being investigated as a novel pharmacological approach to controlling neural excitatory balance (Malayev, A., et al., Br J Pharmacol, 2002, 135:901-9; Maurice, T., et al., Brain Res Brain Res Rev, 2001, 37:116-32; Park-Chung, M., et al., Brain Res, 1999, 830:72-87). The methods encompassed by the present invention may suitably accelerate these efforts by allowing facile screening of endogenous and synthetic neurosteroids for sulfoconjugation, offering insight into the fundamental biology as well as providing a tool for lead molecule identification and optimization. The need for better molecular tools is accentuated by the fact that there is already a sizeable over the counter market for DHEA as an “anti-aging” dietary supplement purported to alleviate age related senility and memory loss (Salek, F. S., et al., J Clin Pharmacol, 2002, 42).

Furthermore, it is envisioned that the methods of the present invention may suitably identify drug targets with respect to cholesterol sulfate in the regulation of cholesterol efflux, platelet aggregation and skin development in treatments for cardiovascular disease and perhaps some forms of skin cancer. In this instance, a sulfotransferase—most likely SULT2B1b—could become the drug target, and molecules that selectively inhibit this isoform may need to be identified. The availability of a full panel of the human SULTs and a robust HTS assay method of the present invention may be valuable to such an effort.

Glucuronidation in Drug Discovery

Drug metabolism problems such as production of toxic metabolites and unfavorable pharmacokinetics cause almost half of all drug candidate failures during clinical trials (Obach, R. S., et al., J Pharmacol Exp Ther, 1997, 283:46-58). All of the major pharmaceutical companies have recognized the need to consider pharmacokinetic and pharmacogenomic consequences early in the drug discovery process resulting in an immediate need for high throughput in vitro methods for assessing drug metabolism. Aside from P450-dependent oxidation, glucuronidation is perhaps the most important route of hepatic drug metabolism. UGTs catalyze the transfer of glucuronic acid from UDP-glucuronic acid to an acceptor molecule such a a drug: Uridine diphosphate-glucuronic acid (UDPGA)+aglycone→UDP+glucuronide

A broad spectrum of drugs are eliminated or activated by glucuronidation including non-steroidal anti-inflammatories, opioids, antihistamines, antipsychotics and antidepressants (Meech, R. and Mackenzie, P. I., Clin Exp Pharmacol Physiol, 1997, 24:907-15; Radominska-Pandya, A., et al., Drug Metab Rev, 1999, 31:817-99). Despite their importance, the broad and overlapping substrate specificity of the hepatic UDP-glucuronosyltransferases (UGTs) that catalyze glucuronidation remains poorly understood because of a lack of flexible in vitro assay methods. The primary reasons for this is that the catalytic assays used require separation of reactants from products, which involves substrate-specific chromatographic steps and thus is not practical in an HTS format.

Two UGT families (e.g., UGT1 and UGT2) have been identified in humans; although the members of these families are less than 50% identical in primary amino acid sequence, they exhibit significant overlap in substrate specificity. The members of the UGT1 family that are expressed in human liver, where the majority of xenobiotic metabolism takes place, include UGT 1A1, 1A3, 1A4, 1A6, and 1A9. Although the UGT2 family has not been studied as extensively, it is known that UGT2B4, 2B7, 2B10, 2B11 and 2B15 are expressed in the liver. Mutations in UGTs are known to have deleterious effects, including hyperbilirubinaemia which occurs with a frequency of 5-12% (Weber, W., 1997) and can lead to neurotoxicity and in severe cases, death. As is the case for other drug metabolizing enzymes such as P450s, interindividual differences in UGT expression levels have been observed and linked to differences in drug responses (Iyer, L., et al., J Clin Invest, 1998, 101:847-54). For instance, low expression of UGT1A1, as in patients with Gilbert's syndrome, has been associated with the toxicity of Irinotecan, a promising anticancer agent (Wasserman, E., et al., Ann Oncol, 1997, 8:1049-51). In addition, UGT upregulation in tumor tissues has been identified as a possible cause of anticancer drug resistance (Franklin, T. J., et al., Cancer Res, 1996, 56:984-7; Takahashi, T., et al., Jpn J Cancer Res, 1997, 88:1211-7).

All of the known UGTs exhibit broad substrate specificity, with a single isozyme catalyzing glucuronidation of a broad range of structurally unrelated compounds; not surprisingly there also is a great deal of overlap in the specificities of UGT isozymes (Radominska-Pandya, A., et al., Drug Metab Rev, 1999, 31:817-99). With regards to biotransformation of endogenous molecules, UGT 1A1 is clearly the predominant isoform involved in glucuronidation of the tetrapyrrole, bilirubin, resulting in its excretion. Beyond this, it is difficult to make generalizations regarding specificity because of the lack of systematic studies with most of the recently identified isoforms. Numerous endogenous steroids have been identified as aglycones for most of the hepatic isoforms include including 1A1, 1A3, 1A4, 2B4, 2B7, and 2B15. Lipids and bile acids serve as substrates for 2B4 and 2B7, and recently retinoids have been identified as substrates for some isoforms from both families. The structural diversity of known xenobiotic aglycones is very broad; it includes many drugs and drug like molecules including tertiary amines such as imipramine, non-steroidal anti-inflammatories (NSAIDs) such as acetominophen and naproxen, opioids such as morphine and codeine, and carboxylic acid containing drugs such as clofibric acid.

It is envisioned that the immunoassay (i.e., FPIA-based donor product assay) for UGTs will be used in a manner very similar to that described for SULTs for determining whether potential drug candidates interact with any of the known UGT isoforms. Using the method of the invention, it will be possible to determine whether compound of interest interacts with a one or more UGT isoforms, and if so, whether it is a substrate or inhibitor. Also one can identify the kinetic parameters (IC₅₀, K_(m), V_(max)) for the interaction between the compound of interest and enzymatic isoform. It should be noted that recombinant forms of the many of the UGT isoforms are already available (Invitrogen, Becton-Dickinson). Kinetic studies with the appropriate UGT isozyme can be used to predict in vivo clearance rates, reducing the number of compounds that fail in clinical studies due to poor pharmacokinetics. Also, the knowledge of metabolism by a specific UGT alerts the drug discovery team to potential pharmacogenetic problems, since genetic differences in UGT levels are recognized as an important factor in varying responses to therapeutics. Furthermore, the identification of the UGT responsible for the metabolism of a drug will aid in judicious selection of the in vitro assays or animal models used for preclinical assessment of possible drug-drug interactions and toxicology testing, thereby reducing inappropriate or unnecessary use of animals for experiments. Also, metabolism data can be used as a component of rational drug design. A better understanding of the structure-activity relationships that define substrate specificity for the various UGT isozymes would provide a basis for structural modifications of primary compounds to change their metabolism profile. Also, the testing of glucuronidated compounds can lead to the discovery of valuable prodrugs that are inactive until metabolized in the body into an active form.

Protein Kinases in Drug Discovery

Protein kinases, catalyze the transfer of the terminal phosphate group from ATP or GTP to serine, threonine or tyrosine residues of acceptor proteins: ATP+Protein→ADP+Protein-PO₄ There are more than 400 distinct kinases encoded in the human genome; elucidating their role in disease and identifying selective inhibitors is a major pharma initiative. Kinase malfunction has been linked to all of the most important therapeutic areas, including cancer, cardiovascular diseases, inflammation, neurodegenerative diseases, and metabolic disorders. Moreover, clinical validation of kinases as drug targets has recently been shown in the cases of Herceptin and Gleevec, which inhibit aberrant tyrosine kinases that contribute to breast cancer and leukemia, respectively. High throughput screening (HTS)—the parallel testing of many thousands of compounds for interaction with a drug target—has become the dominant mode of drug discovery. The total market for HTS assay reagents in 2002 was $474 million, and approximately 20% of screening was done on protein kinases. Despite the high level of interest, pharma efforts to incorporate kinases into HTS programs are hampered by shortcomings with the assay methods. The most commonly used HTS kinase assays rely on fluorescence-based immunodetection of a phosphorylated peptide reaction product, which varies with the substrate specificity of individual kinases. Time consuming reagent development is thus required for each kinase, or group of related kinases, and comparison of results between assays is problematic. To overcome this technical hurdle the invention provides for a FPIA for detection of adenosine diphosphate (ADP), a product of all kinase reactions. This assay will accelerate efforts to define kinase substrate specificity and to identify novel inhibitors by providing a universal catalytic assay that can be used with any kinase and any acceptor substrate.

Protein Kinases are a large, diverse family with a key role in signal transduction. Protein kinases, which catalyze the transfer of the terminal phosphate group from ATP or GTP to serine, threonine or tyrosine residues of acceptor proteins, are one of the largest protein families in the human genome. In the broadest senses, they can be divided into serine/threonine or tyrosine kinases and soluble enzymes or transmembrane receptors. In the most recent and comprehensive genomic analysis, 428 human kinases were identified that comprise eight different homology groups, which also reflect differences in substrate specificity, structure/localization and/or mode of regulation (Hanks, S. K., Genome Biol, 2003, 4:111). For instance, there are 84 members of the Tyrosine Kinase group, which includes both transmembrane growth factor receptors such as EGFR and PDGFR and soluble enzymes such as the Src kinases, 61 members of the cyclic nucleotide dependent group, ser/thr kinases which includes the lipid dependent kinases—the PKC isoforms, and 45 members of the “STE” group, which includes the components of the mitogenic MAP kinase signaling pathway.

Kinases are ubiquitous regulators of intracellular signal transduction pathways, and as such have come under intense focus by pharmaceutical companies searching for more selective therapies for a broad range of diseases and disorders; they are second only to G-protein coupled receptors in terms of pharma prioritization (Cohen, P., Nat Rev Drug Discov, 2002, 1:309-15). Intracellular targets for phosphorylation include other kinases, transcription factors, structural proteins such as actin and tubulin, enzymes involved in DNA replication and transcription, and protein translation, and metabolic enzymes (Cohen, P., Trends Biochem Sci, 2000, 25:596-601). Phosphorylation can cause changes in protein catalytic activity, specificity, stability, localization and association with other biomolecules. Simultaneous phosphorylation at multiple sites on a protein, with different functional consequences, is common and central to the integration of signaling pathways.

Diversity of Phosphorylation Sites.

Each kinase may phosphorylate one or more target proteins, sometimes at multiple sites, as well as autophosphorylate within one or more regulatory domains that control catalytic activity or interaction with other biomolecules. Defining the functional consequences of cellular phosphorylation profiles for normal and disease states is a major proteomics initiative. However, to use this knowledge for deciding which kinases to target for drug discovery, their specificity for acceptor substrates must also be delineated. Kinases recognize specific linear sequences of their target proteins that often occur at beta bends. In general, amino acids that flank the phosphorylated residue for three to five residues on either side define a phosphorylation site. The PhosphoBase database, which compiles known kinase phosphorylation sites, contains entries for 133 human kinases, less than a third of the total kinases. Moreover, most, if not all of these specificity profiles are incomplete, as they only show one or two peptides that have been identified as substrates for each kinase. Though there is significant overlap in substrate specificity among related kinases, there is no consensus sequence that is phosphorylated by a large number of kinases. This situation complicates the incorporation of diverse or novel kinases into HTS assays that rely on detection of specific phosphorylated products.

TABLE 1 Target Structure: Company (Phase) EGFR Small molecule: GlaxoSmithKline (I), Pfizer (II), WyethAyerst (I), AstraZeneca (III), OSI Pharmaceuticals Monoclonal: Imclone (III), Abgenix (II), Merck (I), Medarex/Merck (I) Her2/Neu Monoclonal: Genentech (Herceptin), Medarex/Novartis (I), Genentech (I) PDGFR/ Small molecule: Novartis (Gleevec) cKit/BCR-Abl Raf Small Molecule: Merck, Onyx/Bayer (II) Antisense: Isis Pharmaceuticals (II) MEK Small molecule: Pfizer (II), Promega (I) CDK Small molecule: Aventis (II), Cyclacel (I), Bristol-Myers Squibb (I) PKC Small molecule: Novartis (II), GPC Bioteck (II), Eli Lilly (I) Antisense: Isis (III) Protein Kinases in Cancer

The biological rationale for targeting kinases to intervene in cancer is far too extensive to attempt an overview here. However, one of the dominant themes is the involvement of numerous kinases in controlling the delicate balance between the rate of cell division (cell cycle progression), cell growth (mass), and programmed cell death (apoptosis) that is perturbed in all cancers. Growth factor receptor tyrosine kinases (RTKs) are membrane-spanning proteins that transduce peptide growth factor signals from outside the cell to intracellular pathways that lead to activation of progrowth and anti-apoptotic genes. The majority of the fifty-eight RTKs in humans are dominant oncogenes, meaning that aberrant activation or overexpression causes a malignant cell phenotype. Not surprisingly, tyrosine kinases are being aggressively pursued as anticancer drug targets and both small molecule and monoclonal antibody inhibitors—Gleevec and Herceptin, respectively—have been clinically approved. Downstream signaling from growth factor receptors occurs through multiple pathways involving both ser/thr and tyrosine kinases. One of the dominant kinases is the mitogen activated protein kinase (MAPK) pathway, which includes Raf and MEK kinases; inhibitors of all of these kinases are currently being tested in clinical trials (Table 1) (Dancey, J. and Sausville, E. A., Nat Rev Drug Discov, 2003, 2:296-313). Bolded text refer to approved drugs. Soluble tyrosine kinases, especially the 11 oncogenes that comprise the Src family, also transduce mitogenic signals initiated by RTKs and are being targeted by pharma (Warmuth, M., et al., Curr Pharm Des, 2003, 9:2043-59). Following mitogenic signals through RTKs that initiate entry into the G1 phase, progression through the cell cycle is regulated by sequential activation of phase-specific kinases in association with cyclin proteins. The cyclin dependent kinases represent yet another important group of kinases that pharma is pursuing in the hopes of inhibiting malignant cell proliferation (Table 1) (Elsayed, Y. A. and Sausville, E. A., Oncologist, 2001, 6:517-37).

Kinases as Targets in Other Diseases

Pharma interest in kinases is most intensely focused on cancer, but extends to all of the key therapeutic areas. Table 2 shows recent reviews describing the biological rationale for pursuing kinase targets for a broad range of disorders; note that the targets overlap those being pursued for cancer. Entire companies have formed on the basis of targeting kinases for drug discovery. These include Sugen (http://www.sugen.com, now owned by Pfizer), Signase (http://www.signase.com/index.htm), and ProQinase (http://www.proginase.com/index.html).

TABLE 2 Disease Targets Inflammatory MAPK (Adams, J. L., et al., Prog Med Chem, 2001, diseases, 38: 1-60); MEK1,2 (English, J. M. and Cobb, M. H., arthritis Trends Pharmacol Sci, 2002, 23: 40-5) Type II diabetes GSK-3 (Eldar-Finkelman, H., Trends Mol Med, 2002, and complications 8: 126-32), PI-3 Kinase (Jiang, G. and Zhang, B. B., Front Biosci, 2002, 7: d903-7), PKCβ (Frank, R. N., Am J Ophthalmol, 2002, 133: 693-8), IRTK (Laborde, E. and Manchem, V. P., Curr Med Chem, 2002, 9: 2231-42), PKA (Musi, N. and Goodyear, L. J., Curr Drug Targets Immune Endocr Metabol Disord, 2002, 2: 119-27) Hypertension, PKC, var. isoforms (Malhotra, A., et al., Mol Cell cardiovascular Biochem, 2001, 225: 97-107), Rho Kinase (Chitaley, K., et al., Curr Hypertens Rep, 2001, 3: 139-44) Neuropathy— CDK5 (Lau, L. F., et al., J Mol Neurosci, 2002, 19: Alzheimer's 267-73); MAPK (Dalrymple, S. A., J Mol Neurosci, disease, 2002, 19: 295-9), CKDs (O'Hare, M., et al., stroke Pharmacol Ther, 2002, 93: 135-43) Neuropsychiatric PKC α, PKC ε (Chen, G., et al., Bipolar Disord, disorders 2000, 2: 217-36) Antimicrobials Histidine Kinases (Matsushita, M. and Janda, K. D., Bioorg Med Chem, 2002, 10: 855-67)

It is envisioned that the FPIA-based donor product assay will be used to screen drug libraries for inhibitors or activators of protein kinases. It will also be useful for screening peptides or proteins as acceptor substrates for kinases. In these applications, it will have the significant advantages over other methods such as the universal nature of the assay, simplified homogenous assay, no radioactivity, and the ability to quantify enzyme turnover.

Universal Assay Method

This method will accelerate the incorporation of protein kinases into HTS screening programs because it is truly generic: a single set of detection reagents can be used for all kinases and all acceptor substrates. An important advantage over most of the current assay methods is the capability to use physiological protein acceptor substrates as well as short peptides.

Homogenous

This assay is a single addition, mix and read format. This is an important factor driving decisions on assay selection in an automated high throughput environment (High Tech Business Decisions, M., CA, Commisioned Market Analysis, 2002). In addition, if antibodies with suitable binding kinetics are isolated, it allows a continuous assay format that provides more detailed kinetic information than a stop-time assay.

Fluorescence Detection

By employing fluorescent probes, the FPIA format eliminates radiation handling, disposal and costs. It should be noted that over the last few years FP has become one of the key HTS assay platforms used by pharma (Owicki, J. C., J Biomol Screen, 2000, 5:297-306). It is expected that in 2003 it will be used by pharma in approximately 12% of total primary screening assays; this is a doubling from the level of FP usage in 2001 (High Tech Business Decisions, M., CA, Commisioned Market Analysis, 2002). FP is a standard mode on several commercial HTS plate readers.

Quantitative

In the proposed enzymatic assay, the ADP is produced in stoichiometric amounts with the phosphorylated peptide or protein, thus the use of a standard curve for ADP will allow a direct measure of enzyme turnover. Though the use of FP for HTS applications is a relatively recent development, the use of FPIAs for quantitative detection of hormones and metabolites in a diagnostic setting is very well established (Nasir, M. S. and Jolley, M. E., Comb Chem High Throughput Screen, 1999, 2:177-90).

EXAMPLES Example 1 Uridine Glucuronide Transferase Assay

One embodiment of this application involves detecting the “donor product” of the UGT reaction using a competitive fluorescence polarization immunoassay where the antibody-bound tracer has a high polarization value which decreases when it is displaced by an analyte, such as UDP (as shown in FIG. 2). The main reagent required for this assay is the production of an antibody that binds UDP with high selectivity and has negligible binding to the donor, UDP-glucuronic acid (UDPGA). This highly selective antibody is used in combination with fluorescent UTP compounds (as substitutes for UDP tracers) to establish the assay. The polyclonal antibody produced against UDP required covalent binding of the nucleotide hapten to a carrier protein. UTP was used as the hapten only because reactive derivatives of the triphosphate, but not the diphosphate, were readily available that could be used for conjugation. It was reasoned that the majority of the triphosphate may be hydrolyzed to di- and mono-phosphate in animals. Several different chemistries for linking the UTP to carrier protein were investigated, because the nature of the linkage can have a profound affect on the resulting antibody specificity and affinity for antigen. Care was taken so that the linker molecule was attached to the uridine ring rather than the ribose or phosphate, thus maximizing the immunoreactivity with the portion of the UDP molecule that may differentiate it from the donor, UDPGA. One immunogen that proved particularly useful was 5-aminoallyl UTP (Sigma) conjugated to Keyhole Limpet Hemocyanin using glutaraldehyde.

Tracers were synthesized in a manner similar to immunogens, by conjugating amine-reactive fluors to 5-aminoallyl UTP. Tracers based on fluorescein derivatives such as 5- and 6-fluorescein amine proved useful, but those based on the Alexa fluors (Molecular Probes) proved most suitable as they yielded higher polarization shifts when bound to antibody. Two such UTP tracers which can be used for UGT assay of the invention are shown in FIG. 4. Specifically, FIG. 4A depicts the chemical struture of Alexa Fluor 488/aminoallyl-UTP and FIG. 4B depicts Alexa Fluor 633/aminoallyl UTP. The structure of the allyl linker is an important component of the tracer because it reduces the flexibility of the linker region relative to single bonds, preventing rotation of the fluor and resultant lower polarization values for the bound tracer. Commercially available UTP tracers with alkynyl linkers (Molecular Probes, Corvallis, Oreg.) have also worked well for the same reason. Applicants note that UTP was used for tracer synthesis for reasons of convenience because the aminoallyl derivative was commercially available. Tracers based on UDP have also been synthesized and have been shown to work equally well for the method of the invention, as would be expected.

Selectivity of the Antibody for UDP

To detect UGT catalytic activity a series of experiments were performed using the antibodies and tracers described above. For example, FIG. 5 shows titrations of antibody-tracer complex with various uridine nucleotides using polyclonal antibody raised against a mixture of UTP and UDP conjugated to KLH (UGT-1). The antibody and 2 nM of a commercially available Alexa 488-5-aminoalkynyl-UTP molecule (Molecular Probes) were added to wells of a black multiwell plate (Thermo Labsystems Pt#7605) containing the indicated amounts of uridine nucleotides in 50 mM KPO4pH 7.5, 150 mM NaCl, 0.1 mg/ml BGG. Fluorescence polarization was read in a Tecan Ultra plate reader after several hours of equilibration at room temperature using a Ex₄₈₅/Em₅₃₅ filter set.

It is noted that UTP and UDP compete off the tracer with similar effectiveness, with half maximal values (IC₅₀) of 5 and 15 μM, respectively. In contrast, the donor molecule UDP-glucuronic acid (UDPGA) competes much less effectively, with an IC₅₀ of approximately 2 mM, indicating that this antibody is greater than 100× more selective for the reaction product UDP than the donor molecule, UDPGA using this displacement assay.

The crossreactivity with UTP was expected and is not problematic for the proposed assay because it is not present, nor is it produced, in UGT enzyme reactions. The ability of UDP to displace the tracer at low micromolar concentrations and the inability of UDPGA to do so indicates that this antibody is suitable for detection of UDP produced in UGT enzyme reactions.

Detection of UGT Catalytic Activity

To detect UGT catalytic activity, the assay protocol and the UGT reaction conditions set forth in FIG. 6 were followed. The experimental results of using the UGT-1 antibody and a UTP tracer for detection of UGT enzymatic activity in a multiwell format is shown in FIGS. 7-9. In these experiments a tracer synthesized from 5-aminoallyl UTP (Sigma), Alexa Fluor 488 (FIG. 4) and various commercially available sources of UGT enzymes were used. The dependence of the assay signal on time and UGT enzyme concentration is shown in FIG. 7. UGT assays were performed in 35 μl volumes with varying amounts of UGT 2B7 Baculosomes™ (Invitrogen), 100 μM hyodeoxycholic acid (HDCA), and 70 μM UDPGA in the present of the anti UDP/UTP Ab/tracer complex. The UTP tracer was synthesized in-house with AlexaFluor™ 488 (Molecular Probes). The standard assay buffer consisted of 50 mM KPO₄(pH 7.5), 150 mM NaCl, 5 mM MgCl₂, and 1% DMSO (v/v). Incubations were at 37° C. Δ mP=mP (reaction with acceptor)−mP (reaction without acceptor).

The dependence of the assay signal on acceptor substrate concentration is shown in FIG. 8. Similarly, UGT assays were performed in 35 μl volumes with 300 μg/ml of UGT 2B7 Baculosomes™ (Invitrogen), varying amounts of hyodeoxycholic acid (HDCA), and 70 μM UDPGA in the presence of the anti UDP/UTP Ab/tracer complex. The UTP tracer was synthesized in-house with AlexaFluor™ 488 (Molecular Probes). The standard assay buffer consists of 50 mM KPO₄(pH 7.5), 150 mM NaCl, 5 mM MgCl₂, and 1% DMSO (v/v). Incubations were at 37° C. The experiments in FIGS. 7 and 8 were done with recombinant UGT 2B7 and hyodeoxycholic acid as an acceptor substrate.

FIG. 9 shows that the UGT assay can be used to detect glucuronidation of diverse acceptor substrates by different UGT isoforms, clearly illustrating the universal nature of the method. In this experiment a variety of UGT enzyme sources and acceptor substrates were tested in the UGT assay. The enzyme protein concentration and the acceptor substrate @100 uM) for each of the reactions are as follows: 2B7 Supersomes™ (BD Biosciences)(50 ug/ml, HDCA), HEK293 2B7 microsomes (kind gift from Dr. Anna Radominska-Pandya)(50 ug/ml, HDCA), 2B7 Baculosomes™ (300 μg/ml, HDCA), 1A1 Baculosomes™ (300 μg/ml, octylgallate), 1A6 Baculosomes™ (300 μg/ml, 1-naphthol), and Human Liver Microsomes (HLM; XenoTech)(50 ug/ml, HDCA). It is noted that the reported ΔmP values are near the maxima achieved with a titration of enzyme; protein concentrations were based on vendor-supplied information.

Applicants further note that the ability of the antibody to selectively recognize low micromolar concentrations of UDP in the presence of UDPGA concentrations typically used for UGT assays—50-100 μM—is important for achieving a low signal to background. Varying the structure of the immunogen, as mentioned above, is one way to change the relative binding properties of antibodies for UDP and UDPGA. Another way that is not as immediately obvious is to vary the tracer structure. The method depends on the relative ability of UDP and UDPGA to competitively displace the tracer from antibody, and it is reasonable to assume that not all tracers will show the same relative response to the two nucleotides. An example of such tracer effects is summarized in FIGS. 10A and B. In this example, two different tracers are compared. The tracers are conjugates of 5-aminoallyl UTP to two different amine reactive Alexa Fluors, one with an excitation peak of 546 and the other with an excitation of 568. Both of these tracers are displaced from antibody (anti-UDP rabbit polyclonal Ab or UGT-1) in a similar manner by UDP. IC₅₀ values of 7 and 9 μM were observed for the Alexa 546 and Alexa 568 tracer, respectively. However, displacement by UDPGA differs significantly for the two tracers, with IC₅₀ values of 1.2 and 6.4 mM observed for the Alexa 546 and Alexa 568 tracer, respectively. Thus, the signal to background of the UGT assay with a given antibody can be enhanced by identifying tracers that are displaced by UDP more effectively than UDPGA.

Signal Stabilization and Reaction Quenching

UGT enzymes are available only as crude membrane preparations that contain many other enzymes besides the desired UGT. Some of these contaminating enzymes can catalyze hydrolysis of the UDP molecule to UMP or Uridine, resulting in an unstable signal for the assay. To prevent this, agents such as sodium vanadate and EGTA are added to stabilize the assay signal by preventing breakdown of the UDP formed during the UGT reaction. To demonstrate effective signal stabilization and reaction quenching, mock UGT reactions were set up using standard conditions (50 mM KPO₄ pH 7.5, 5 mM MgCl₂, 0.7% v/v UGT Assay Antibody 1, 1 nM 488-UTP Tracer, 300 ug/mL UGT 2B7 Baculosomes™, 70 μM UDPGA) but lacking an acceptor substrate, so no enzymatic turnover would occur. UDP (5 μM) was added to simulate a situation where the reaction is complete and the plates are sitting waiting to be read.) As shown in FIG. 11, EGTA at 80 mM very effectively inhibits UDP breakdown, but has minimal effects on UGT activity and fluorescence polarization values so it can be included in UGT reactions. Sodium vanadate at 30 mM prevents UDP breakdown and in addition very effectively inhibits UGT activity, so it is added after the UGT reaction is complete to quench the reaction and and stabilize the assay signal. The use of such a quenching reagent provides greater flexibility in experimental protocols because HTS assay plates may be read at any time after the quench reagent is added.

Despite their importance, the substrate specificity of the hepatic UDP UGTs that catalyze glucuronidation remain poorly understood because of a lack of flexible in vitro assay methods. The primary problem is that the catalytic assays used require separation of reactants from products, which involves substrate-specific chromatographic steps and thus is not practical in an HTS format. By establishing the concept for measuring the UGT reaction product, UDP in a fluorescent, homogenous format, the applicants have provided the technical foundation for solving this problem. Because the assay measures a product common to all UGT reactions, it allows a single mode of detection with any UGT isoform and any substrate. In addition, the method does not require separation of reactants from products, and is a significant improvement over other related assays because it uses fluorescence detection rather than calorimetric, making it more sensitive and more desirable for pharma HTS platforms, which have become largely reliant on fluorescence based detection. Also, it is a continuous assay method, thus can provide real time kinetic data on UGT enzyme turnover. In addition the antibody-antigen binding reaction is less susceptible to interference from test samples than a conventional coupled enzyme reaction that has been used in the past for donor product detection (Mulder, G. J. and A. B. D. Van Doorn, Biochem J., 1975, 151: p. 131-40). Thus, the novel assay method will enable screening of diverse compounds for metabolism by a panel of isolated UGT isozymes, which will greatly enhance preclinical metabolism studies, and potentially reduce the clinical attrition rate.

Example 2 Assays for Other Types of Glycosyltransferases

Glucuronic acid is one type of carbohydrate molecule that is activated by UDP for enzymatic transfer to other biomolecules; there are many other types of group transfer reactions that use UDP-sugar as an activated donor. These include protein glycosyltransferases that modulate the cellular localization and/or secretion of proteins via their carbohydrate modifications and biosynthetic enzymes that incorporate sugar monomers into polymers such as glycogen and bacterial peptidoglycan. Many of these enzymes are potential targets for therapeutic intervention, both in humans or for antimicrobials.

One class of microbial glycosyltransferases that are of interest from a drug discovery perspective include transferases involved in bacterial cell wall synthesis such as the UDP-galactofurnosyltransferase of Mycobacterium tuberculosis (Cren, S., Gurcha, S. S., Blake, A. J., Besra, G. S., Thomas, N. R. Org. Biomol. Chem. 2; 2418-2420. A mammalian glycosyltransferase that is of potential interest from therapeutic perspective is the O-linked protein glycosyltransferase (OGT), which transfers N-GlcNAc to serines and threonines of proteins, regulating their activity in a manner similar to phosporylation (Zachara, E. N., and Hart, G. W., Biochim. Biophys Acta 1673: 13-28.) These and many other sugar transferases use UDP-activated donor molecules and thus can be detected using an anti-UDP antibody and UTP or UDP tracers described above, or similar antibody and tracer pairs. In addition, there are other classes of glycosyltransferases that use TDP- or CDP-activated donors which may also be detected with similar reagents using the invention herein. An antibody raised against UDP as described herein may have suitable cross reactivity for different purine diphosphates to be used for glycosytransferases that produce CDP or TDP. Alternatively, different antibodies can be raised against these specific nucleotides.

Example 3 Kinase Assays

To develop an anti-ADP antibody, 6-aminobutyl-ADP (Biolog Life Science Inst., Bremen, Germany) was conjugated to keyhole limpet hemocyanin with a suitable reagent such as glutaraldehyde and used to immunize rabbits. Other carrier proteins such as BSA or ovalbumin and other conjugation chemistries may be used. Attachment to carrier protein via the adenine ring exposes the ribosyl-phosphate moiety, where selectivity is required, and minimizes exposure of the adenine ring. The resulting antisera was tested for ADP binding affinity and selectivity in competitive fluorescence polarization binding assays. Synthesis of the fluor-ADP conjugates used as tracers in these binding assays is described below. Crude serum from naïve rabbits can exhibit high background binding to ADP tracers, so the antiserum was purified using immobilized Protein G (Pierce, Rockford, Ill.) to isolate the IgG fraction. To show that ADP displaced tracer from the purified ADP polyclonal antibody much more effectively than ATP, applicants conducted a series of FP competition experiments using 5-FAM-N-6-ADP tracer. The reaction mixtures consisted of 50 mM KPO₄, 150 mM NaCl, 0.1 mg/mL BGG, 1 nM tracer, 3% Protein G-purified Anti-ADP antibody, and competitor. The reaction mixtures were incubated for 19 hours at room temperature. Competitors included ADP (∘), ATP (●), Adenosine (▪), and AMP (▴). These results are shown in FIG. 12. The half maximal point in the competition curve (IC₅₀) for ADP is 300 nM, whereas for ATP it is 15 μM; much higher amounts of AMP and adenosine are required to displace the tracer. These results prove that it is possible to generate antibody with high selectivity for ADP versus ATP, in this case a 50× difference was achieved. They also indicate that the phosphodiester bond in ADP is sufficiently stable in serum to allow an immune response to ADP with very little cross-reactivity to AMP, eliminating the need to use a non-hydrolyzable ADP analog for an immunogen. It should be noted that the use of nonhydrolyzable ADP analogs might enable the development of more selective antibodies.

In addition to the antibody production in rabbits, initial efforts to generate monolconal antibodies in mice were undertaken, and yielded antibodies with properties similar to the polyclonal serum described above. The monoclonal efforts included the use of immunogens based on conjugation of carrier proteins to both the N6- and C8-positions in the adenine ring. Attachment at the N6 position of adenine yielded approximately 50× selectivity for ADP whereas attachment at the C8 position yielded less.

Tracer Synthesis

Tracers were synthesized by conjugating fluors to the N6 and C8 positions in the adenine ring using different linkers. Amine reactive fluors were conjugated to N6-aminobutyl ADP as shown for example in FIG. 13. To synthesize fluorescein-ADP conjugate used as tracer for competitive binding experiments, applicants added to 50 μL of N6-aminobutyl-ADP (Sigma) (54.3 mg/mL), 12 μL of 5-Fluorescein amine-N-succinimidyl ester (Molecular Probes) (20 mg/mL) followed by 138 μL of dimethyl sulfoxide. The reaction mixture was shaken for 72 hours and products were purified via preparative thin layer chromatography (Whatman LK-6F) using 70:30 Ethanol/2 ml ammonium acetate. Fluorescent bands were scraped off and desorbed using 1:1 Methanol/2 mM ammonium acetate, pH 5.5.

Attachment to the C8 of adenine required bromination of ADP, which occurs predominantly at C8, and subsequent nucleophilic displacement using diamino-alkanes, was followed by reaction with amine-reactive fluors. Initially, applicants limited fluors to fluorescein derivatives because there were numerous reactive derivatives available and because fluorescein was relatively hydrophilic, so generally yields tracers with low surface binding properties. Synthetic reactions with several combinations of ADP-linker molecules and amine reactive fluoresceins were run and the fluorescent products resolved by thin layer chromatography (TLC). HPLC can also be used for additional purification of tracer molecules if necessary.

The 5- and 6-fluorescein amine (FAM) conjugates to N6-aminobutyl ADP used for kinase assays exhibit highest affinity binding for the anti-ADP antibody used in initial studies. These FAM tracers were used in the competitive binding experiments as shown in FIG. 12. None of the tracers made from conjugates to the adenine C8 showed high affinity binding to antibody. Tracers based on Alexa fluors (Molecular Probes, Corvallis, Oreg.) were synthesized using similar methods and showed antibody binding and fluorescence polarization properties similar or better than the fluorescein based tracers. Tracers based on Alexa fluors include for example, Alexa Fluor 488/6-aminobutyl ADP and Alexa Fluor 633/6-aminobutyl ADP as shown in FIGS. 14A and B, respectively.

The N6-aminobutyl ADP-5-FAM tracer and rabbit antiserum was used to detect Protein Kinase A (PKA) activity. In 384-well, black CliniThermo plates, various amounts of PKA were preincubated at 30° C. with kemptide substrate (Sigma, St, Louis, Mo.) in the presence of tracer/antibody complex. ATP was then added to start the reaction. The final assay conditions were 50 mM HEPES buffer (pH 7.5), 1 mM EGTA, 0.1 mg/ml BGG, 50 uM kemptide substrate, 10 uM ATP, and 10 mM MgCl₂, 1 nM fluorescein-labeled tracer (N-6-AB-ADP-5FAM), and rabbit anti-ADP proteinG-purified polyclonal antibody in a total volume of 30 uL. The following amounts of PKA were used: ▪, 3.0 ng, ♦, 0.3 ng, ▴, 0.2 ng. Reactions lacking PKA were used as controls. FIG. 15 shows the assay results for PKA using FPIA. As shown in FIG. 15, the slope of the assay response curve over time increased with increasing amounts of PKA as would be expected for an enzymatic reaction. The Alexa Fluor tracers were used in similar experiments with both polyclonal and monoclonal antibodies for detection of PKA activity. In this example the acceptor substrate used was a small peptide, but a peptide or an intact protein could also be used which is not possible with many of the other currently available kinase assay methods.

Furthermore, it is noted that in screening for inhibitors, the compounds to be tested are generally dispensed into wells prior to addition of any other assay components. Control wells with no inhibitor added are also included for comparison.

Example 4 Sulfotransferase Assays

Expression and Purification of SULT1E1

In order to establish a sulfotransferase HTS assay method, SULT1E1, a SULT isoform, was first subcloned into an E. coli expression vector with a C-terminal 6× histidine tag and the expressed protein was purified by affinity chromatography and characterized with respect to its physical and enzymatic properties.

The V_(max) and estradiol K_(m) values determined for the purified SULT1E compared favorably with published values for purified recombinant SULT1E1, which are 30-40 nmol/min/mg and 5-15 nM, respectively. The published data on acceptor substrate specificity is more varied, but the results reflect the general trend that estradiol and estrone are very good substrates, α-naphthol is intermediate, and DHEA and dopamine are very poor substrates. Thus, all of the SULT1E1 constructs applicants expressed showed native substrate specificity and catalytic rates similar to the highest published values.

Synthesis of Antigens and Generation of Antibodies

Development of the proposed FPIA-based SULT assay method requires an antibody that specifically binds the product of the SULT reaction, PAP, in the presence of excess PAPS; i.e., an antibody that discriminates on the basis of a single 5′-sulfate group. There is ample precedent for antibodies that discriminate between various nucleotides that differ only in the number of phosphates, which is similar in size and structure to a sulfate group as described above. However, there was no precedent for generation of antibodies that specifically recognize PAP.

Small molecules like PAP must be conjugated to a carrier protein in order to be used as an immunogen. Suitably, an antigen density of 10-20 per carrier protein is optimal. As discussed above, the two elements of our antigen synthesis strategy were a) synthesis and testing of several antigens because the site of attachment to nucleotide and linker structure can profoundly affect the properties of the resulting antibodies (Crabbe, P., et al., J Agric Food Chem, 2000, 48:3633-8; Signorini, N., et al., Chem Res Toxicol, 1998, 11:1169-75; Oda, M. and Azuma, T., Mol Immunol, 2000, 37:1111-22), and b) conjugation via the adenine ring because this may allow free exposure of the 5-phosphate group and limit immunoreactivity with the adenine portion of the molecule, resulting in antigens with the desired specificity. None of the nitrogens in the adenine ring were reactive enough to conjugate directly to protein or via crosslinking reagents, so reactive PAP derivatives were used as a starting point; the only commercially available reagent was N6-aminohexyl PAP. What initially appeared to be the most straightforward approach—reacting N6-aminohexyl-PAP with carrier proteins by carbodiimide coupling or amine-reactive crosslinkers—generated unacceptably low antigen density, despite a significant experimental effort.

To pursue alternative chemistries applicants synthesized the following photoreactive molecules: 2- and 8-azido-PAP and C8-hexylamino-PAP (FIG. 16). FIG. 16 shows the synthesis of PAP antigens. 2- and 8-azido-PAP, which were custom synthesized by ALT, Inc. (Lexington, Ky.) were irradiated (254 nm) in the presence of BSA; unreacted nucleotides were removed by filtration and dialysis. Final antigen densities of 7-12 PAP/BSA were obtained as determined by absorbance of the adenine ring (shifted to 270-280 nm). Rabbits (3 per antigen) were immunized by Lampire Biologicals (Ottsville, Pa.). N6-aminohexyl PAP (Sigma) was conjugated to KLH using glutaraldehyde and injected into three rabbits by Biosynthesis Corp. (Lewisville, Tex.). Immunization schedules were similar for all antigens and included 3-4 injections over a 4-6 week period.

Antigens from the two photoreactive PAP derivatives were produced and sent out for antibody production. The generation of antigen from N6-aminohexyl PAP using glutaraldehyde crosslinking to KLH and production of antibody was contracted out to a separate company (FIG. 16). All three antibodies were reported by the contract producers to bind PAP as determined by ELISA (data not shown).

In addition, applicants synthesized the reactive derivatives N6-carboxymethyl PAP and 2′-O-succinyl-PAP (FIG. 17); antibodies from these derivatives have not yet been produced. A detailed description of Ab binding properties using competitive FPIA is provided below following the description of tracer synthesis.

Synthesis of PAP-fluor Tracers

An FPIA tracer molecule can be divided into three different structural components: the antigen, the fluor, and the linker used to join them; an additional key structural variable is the site of attachment of the linker to the antigen. Because identification of a tracer is largely empirical, applicants used a variety of linkers to join PAP and fluorescein via different sites on each molecule; in most cases the final linker region is a composite of the reactive fluorescein and PAP molecules used.

The antibody strategy was to conjugate through the adenine moiety in order to generate antibodies that bind specifically to the ribosyl-phosphate group of PAP. The same sites are the obvious sites for fluor conjugation as well in order to leave the desired immunoreactive portion of the tracer molecule free to bind Ab. Also, fluorescein was the preferred fluor used for conjugation. Though red-shifted fluors such as rhodamine are more desirable for HTS applications, development of FP tracers with fluorescein is usually more straightforward because it is less prone to non-specific binding effects and there are numerous activated derivatives available. As to the linker molecule, it affects tracer characteristics in a number of important ways that impact both its antigenic and fluorescence properties. There is generally a balance that must be struck between separating the antigen from the fluor enough to allow unhindered interaction with antibody without creating too much freedom of motion for the fluor. The former can result in lowered affinity Ab binding and in quenching of the fluor, whereas the latter reduces the polarization shift upon Ab binding, thereby reducing the dynamic range of the assay.

N6-aminohexyl PAP was the only activated PAP molecule used for immunogen synthesis that was useful for tracer synthesis; the photoactivation reactions required to conjugate the two azido-PAP derivatives may be inefficient for joining two small molecules. To provide PAP molecules activated at different positions and with different linker regions, applicants outsourced the production of C8-aminohexyl-PAP and synthesized in house two PAP derivatives with carboxy-terminal linkers: N6-carboxymethyl-PAP and 2′-O-succinyl-PAP. Though the latter compound is linked through the ribose hydroxyl rather than the adenine, this approach has been used to generate highly specific antibodies and tracers for cAMP (Horton, J. K., et al., J Immunol Methods, 1992, 155:31-40).

Below are brief descriptions of the synthesis and purification of activated PAP molecules and their conjugation to various activated fluors; tracer synthesis components are summarized in FIGS. 17 and 18. In general, PAP molecules with amino-terminal linkers were conjugated to fluors activated with succinimidyl esters (or isocyanate in one case) and PAP molecules with carboxy-terminal linkers were reacted with fluorescein derivates containing free amino groups using carbodiimide coupling.

FIG. 17 illustrates structures of components of Tracer Synthesis. FIG. 17 from left to right provides PAP molecules with amino-terminal linkers attached at the C8 and N6 position, amine- and carboxy-reactive fluorescein derivatives, and PAP molecules with carboxy-terminal linkers at the N6 and 2′-OH. The fluorescent PAP conjugates were separated by TLC and tested for binding to anti-PAP antibodies. In accordance to the invention, sixteen reactions were run containing different combinations of PAP and fluorescein derivatives and each reaction yielded 1-4 fluorescent products that could be resolved by TLC. In all, more than 40 tracers have been purified and tested for binding to Ab. N6-aminohexyl PAP (Sigma) and all of the reactive fluorescein derivatives (Molecular Probes) are commercially available. 2′-O-succinyl-PAP and N6-carboxymethyl-PAP were synthesized as described below; C8-aminohexyl PAP was synthesized by Jena Biosciences (Jena, Germany). FIG. 18 provides representative final tracer structures.

Preparation of N6-carboxymethyl PAP

To prepare N6-carboxymethyl PAP, 100 mg PAP was incubated with 0.3 g Iodoacetic acid in 1.2 mL aqueous, adjusted to pH 6.5 with LiOH. The reaction proceeded at 30° C. for 5-7 days, periodically adjusting the pH to 6.5. The resulting 1-carboxymethyl-PAP product was precipitated with ethanol and reconstituted in distilled water and the pH was adjusted to 8.5 with LiOH. This reaction was heated at 90° C. for 1.5 hours to yield the N6-carboxymethyl PAP. This product was purified on a Dowexl-X2 (200-400 mesh) column equilibrated in 0.3 M LiCl, pH 2.75. A gradient was applied over 10 column volumes using 0.5M LiCl, pH 2.0. N6-carboxymethyl PAP eluted off the column as pure product and was confirmed by mass spectral analysis, ˜20% yield.

Preparation of 2′-O-Succinyl-PAP

To prepare 2′-O-Succinyl-PAP, 10 mg (0.024 mmole) PAP and succinic anhydride (43 mg, 0.426 mmole) were dissolved in distilled H₂O containing 10% triethylamine (v/v, 1 mL) and shaken for 1.5 hours with reaction progress monitored using reverse phase thin layer chromatography (RP-TLC). Upon completion, the reaction was lyophilized twice to ensure no residual triethylamine remained. The expected succinate was column purified using Fast Flow Sepharose-Q resin (Pharmacia) equilibrated with 50 mL 250 mM NH₄OAc, and eluted with a linear gradient of 500 mM to 750 mM NH₄OAc (50 mL of each). Fractions containing the product were concentrated on a rotovap followed by lyophilization to furnish 8.4 mg or 67% yield as determined by absorbance measurement. Stock solution was stored at −20° C. for future use.

Preparation of Fluorescein Conjugates with Amino-activated PAP

To prepare fluorescein conjugates with amino-activated PAP, 10 μL of a 100 mM solution of N6- or C8-aminohexyl-PAP in distilled H₂O was combined in a screw cap vial with a molar equivalent of a fluorescein succinimidyl ester, the reaction was brought to a final volume of 200 μL using anhydrous dimethyl sulfoxide (DMSO), and shaken on a vortexer for 24 hours. Reaction progress was followed by RP-TLC using H₂O as the developing media. Reaction products were purified using preparative TLC on normal phase silica gel using 1:1 EtOH/0.5 M NH4OAc. Fluorescein labeled compounds—generally 3-5 produced in each reaction—were visualized using UV light, scraped from the TLC plates, and extracted from the silica gel using 1:1 MeOH/0.5 M NH4OAc. Individual fractions were shaken on a vortex for 1 hour wrapped in aluminum foil and centrifuged at 4000 RPM for 8 minutes. The supernatants were transferred to a separate labeled vial and the extraction process repeated. Combined supernatants were standardized to 50 nM solution for future use and frozen in amber microfuge tubes at −20° C.

Preparation of Fluorescein Conjugates with Carboxy-activated PAP

To prepare fluorescein conjugates with carboxy-activated PAP, 10 ml of a 100 mM solution of N6-carboxymethyl-PAP or 2′-O-succinyl-PAP in distilled H₂O was combined with 50 equivalents of 1-ethyl-3-(dimethylaminopropyl) carbodiimide (EDC) (10 μL of a 1M solution in anhydrous DMSO) followed by 75 equivalents of N-hydroxysuccinimide (15 μL of a 1000 mM solution in anhydrous DMSO), the reaction was brought to an intermediate volume of 180 μL with anhydrous DMSO and shaken for 48 hours. One molar equivalent (20 ml) of fluorescein derivative with a free primary amine was then added and the reaction was incubated with vortexing for 24 hr. Reaction progress was followed by RP-TLC using H₂O as the developing media. Upon completion of the reaction, fluorescent products were purified by normal phase silica TLC and eluted as described above, except that 9:1 acetonitrile/2 mM NH4OAc, pH 5.5 was used as the TLC solvent and 8:2 acetonitrile/2 mM NH4OAc, pH 5.5 was used for elution.

A total of 16 unique combinations of activated PAP and fluorescein molecules were reacted and from these, more than 40 fluorescent products were isolated and tested for binding to antibodies. This approach can be viewed as sort of a “poor man's combinatorial chemistry,” applicants have found it to be very successful for development of FP tracers in other instances. It is noted that the homogenous nature of FP assays and the availability of multiwell instruments makes the screening efforts relatively rapid.

Characterization of Anti-PAP Antibodies and Tracers

In a competitive FPIA, the signal is proportional to the difference in the bound versus free tracer fractions, thus both the dynamic range and the sensitivity of the assay are dependent upon the affinity of the antibody for the tracer and the competing sample molecule. To establish a suitable dynamic range for an FPIA, at least 70-80% of the tracer must be bound to antibody in the absence of competitor. This normally is achieved by using the tracer at a concentration 2-10 fold below the K_(d) and the antibody at a concentration 2-3-fold over the K_(d). The useful concentration range of the assay then ranges from several-fold below the K_(d) concentration to about 20-fold over the K_(d) concentration. For example, if the K_(d) for the tracer/antibody complex is 10 nM, then the range of detection for the sample may be from about 2 nM to about 200 nM. If the K_(d) is ten fold less (1 nM), the sensitivity of the assay also improves about 10-fold.

Acceptable properties for anti-PAP antibody and tracer in terms of the assay parameters affected are defined as 1) dynamic range: low tracer polarization in the absence of Ab (<100 mP) and maximal difference in polarization between the bound and free states (Δ mP>100 mP); 2) sensitivity: high affinity binding of tracer to the anti-PAP antibodies (K_(d)<1 μM), displacement by free PAP with a similar IC₅₀, and minimal fluorescence quenching caused by binding; 3) signal/noise: high Ab selectivity; i.e., competitive displacement of tracer by PAP and not by PAPS or other adenine nucleotides; also lack of tracer interaction with SULT1E1 or other assay component; and 4) a continuous assay: rapid association/dissociation kinetics.

Results of Ab-tracer Interaction Studies

Initial screens for Ab-tracer binding were done by adding several concentrations of each antibody to 1 nm tracer in multiwell plates and monitoring for increases in tracer polarization. With all of the antibodies, purification of IgG fractions using immobilized Protein A or Protein G was required to remove non-specific binding components. All of the data shown is using antibodies purified on Protein G (Pierce Nab™ Protein G Spin Chromatography Kit). Tracer/Ab combinations that showed an interaction in the initial screen were analyzed in more detail for competitive displacement by PAP and selectivity of PAP over PAPS. A total of nine purified antibodies (3 antigens×3 rabbits) were tested for binding with 44 different fluorescein-labeled PAP tracers. All assays were done in black 96-well plates or black low-volume 384-well plates, which gave essentially identical results, and polarization values were read on a Tecan Ultra with a fluorescein filter set (excitation at 485 nm to emission at 535 nm) (Ex₄₈₅/Em₅₃₅).

The binding isotherms in FIG. 19 were generated using the three antibodies and two tracers shown in Table 3 below, and are representative of experiments used to screen antibodies and tracers for binding. Shown are the N6-PAP-F8 tracer binding to Abs 1781 ◯, 1810 ⋄, and 3642 □, and C8-PAP-F14 tracer with the same antibodies: 1781 ●, 1810 ♦, 3642 ▪. Antibodies were serially diluted two-fold in 50 mM phosphate buffer (pH 7.4) containing 150 mM NaCl, 0.1 mg/mL BGG, and 1 nM tracer in a total volume of 100 uL in a 96-well plate or 12 ul in 384-well plates (results in the two plates are identical) and polarization values were read on the Tecan Ultra after one hour incubation at room temperature.

TABLE 3 Representative antibodies and tracers Abbreviation Description Ab 1781 8-azido-PAP-BSA immunogen Ab 1810 2-azido-PAP-BSA immunogen Ab 3642 N6-aminohexyl-PAP-KLH immunogen N6-PAP-F8 N6-aminohexyl-PAP conjugated to 6-carboxyfluorescein succinimidyl ester C8-PAP-F14 C8-aminohexyl-PAP conjugated to 6-carboxyfluorescein succinimidyl ester

The binding properties of antibodies generated from the same immunogen in different animals were similar, but not identical. In this experiment, the 3642 antibody bound both tracers significantly tighter than 1781, and 1810 did not bind either tracer even at the highest concentration tested. The maximal polarization values for 3642 binding to N6-PAP-F8 and C8-PAP-F14 were 140 and 300 mP, respectively; unbound tracer polarization was approximately 20 mP, so the shift observed is more than adequate for use in an FPIA. To test whether binding is specific, competitive displacement by PAP was assessed.

FIG. 20 shows PAP and PAPS competition curves for Ab 3642 and the same two tracers, PAP and PAPS. N6-PAP-6F8 tracer is represented by the open symbols: ◯(PAP), □ (PAPS). C8-PAP-F14 tracer is represented with the closed symbols: ● (PAP), ▪ (PAPS). PAP or PAPS was serially diluted two-fold in black mutiwell plates containing 50 mM phosphate buffer (pH 7.4), 150 mM NaCl, 0.1 mg/mL BGG, 1 nM C8-PAP-F14, and 1.5 uL purified Ab 3642 in a total volume of 12 μl or 1 nM N6-PAP-F8 and 0.5 uL 3642 Ab in a 20 uL volume. Polarization values were read after one hour at room temperature.

The IC₅₀ for PAP with the C8-PAP-F14 tracer is 300 nM, low enough to allow use of these reagents for monitoring SULT1E1 activity. Note that a much higher concentration of PAP (and PAPS) is required to compete off the tighter binding N6-PAP-F8 tracer. This may be because in this case the tracer has the same linker group as the immunogen used to generate antibody, and a population of antibody is recognizing the linker, making the tracer more difficult to displace with free PAP. FIG. 20 also shows that PAPS is less effective than PAP at displacing the tracers from Ab 3642.

Similar results were observed with the 1781 Ab as shown in FIG. 21, which includes complete curves for PAP, PAPS and several similar molecules in competition experiments with the C8-PAP-F14 tracer. FIG. 21 shows competition curves with two anti-PAP antibody/tracer combinations. Competitors were serially diluted two-fold in a black 384-well microtiter plate containing 50 mM phosphate buffer (pH 7.4), 150 mM NaCl, 0.1 mg/mL BGG, 1 nM Tracer C8-PAP-F14, and either 1.5 uL Ab 3642 (A) or 3 uL Ab 1781 (B) in a total volume of 12 uL. After one hour incubation at room temperature, the polarization values were read on a Tecan Ultra (Ex₄₈₅/Em₅₃₅). The mean and standard deviation of duplicates for all data sets are shown. The IC₅₀ values for PAP and PAPS with the 3641/tracer and 1781/tracer combinations were 0.3 uM PAP, 3.8 uM PAPS; and 0.3 uM PAP, 1.5 uM PAPS, respectively.

The 1781 and 3642 antibodies exhibited a 5- and 13-fold selectivity for PAP over PAPS respectively, and much higher selectivity for PAP over all of the other nucleotides tested. The cross reaction with PAPS is higher than expected given the lack of cross reaction with other adenine nucleotides. In this regard, it should be noted that most commercial PAPS preparations contain a significant fraction of PAP, but applicants purchased HPLC-purified preparations that were analyzed at greater than 95% purity, and took precautions in its storage and use to prevent hydrolysis. In any event, these results clearly show that applicants can generate antibodies that bind selectively to PAP in the presence of PAPS, which is a key feasibility issue for allowing sufficient signal:noise and dynamic range in the proposed SULT assay.

The results observed with other antibodies and tracers tested were similar. The additional antibodies produced from the N6-aminohexyl-PAP-KLH and 8-azido-PAP-BSA immunogens bound many of the tracers and the Ab/tracer complexes could be displaced in all cases by unlabeled PAP, indicating that the interaction was specific. The 1810 antibodies showed very poor or no tracer binding and were not tested further. The polarization of the free tracers ranged from 15-40 mP and increases observed upon Ab binding ranged from less than 100 mP to almost 300 mP. Interaction with some tracers was too weak to allow saturation with Ab, so maximal polarization changes were not always observed. More than ⅔ of the tracers tested bound to both types of Ab, but none of the tracers synthesized from N6-carboxymethyl-PAP bound to antibodies generated from either immunogen.

The FPIA-based SULT Assay

Though applicants will need to produce an antibody that differentiates between PAP and PAPS more effectively to develop a high quality assay, applicants were able to use the 3642 Ab and C8-PAP-F14 tracer to monitor detection of PAP produced in reactions containing the purified SULT1E1-cHis. In the initial experiment applicants sought to identify the optimal PAPS concentration for maximal signal:noise. SULT1E1-cHis was incubated with estradiol and varying concentrations of PAPS in the presence of pre-formed Ab-tracer complex; SULT1E1 was present at a level sufficient to rapidly drive the reactions to completion (FIG. 22).

FIG. 22 illustrates the effect of PAPS concentration on detection of enzymatically generated PAP. The assay mixture included 200 ng of SULT1E1-6×His (□) or assay buffer (▪) was added to wells containing 30 mM phosphate (pH 7.4), 7 mM DTT, 8 mM MgCl₂, 75 mM NaCl, 0.5 mg/mL BGG, 150 nM estradiol, 1 nM C8-PAP-F14 tracer, 12.5 uL Ab 3642, and varying concentrations of PAPS in a total assay volume of 100 μL. The plate was incubated for 24 hour at 37° C. and read in a Tecan Ultra (Ex₄₈₅/Em₅₃₅).

As in a typical FPIA, the tracer was used at a concentration well below the K_(d) and the Ab was adjusted to a concentration that resulted in approximately 85% of maximal tracer polarization in the absence of competitor. FIG. 22 shows that there is a range of PAPS concentrations—from approximately 1 to 5 mM—where the enzymatically produced PAP causes a decrease in tracer polarization of approximately 40 mP (the difference between the open and solid squares in FIG. 22).

That is, even though this antibody cross-reacts with PAPS significantly, it can be used in a competitive FPIA mode to detect PAP produced in a SULT reaction with saturating PAPS (K_(m) for PAPS with SULT1E1 is approximately 50 nM) with a dynamic range of 40 mP. Moreover, these were homogenous reactions, or single addition reactions, in which all of the reaction and detection components were added at the start of the reaction, which is the preferred approach for an HTS assay. Similar results are attained if the detection reagents are added after the enzymatic reaction is complete, thus the polarization signal is not affected by the enzymatic reaction (data not shown).

Described above is an embodiment of how one of the Ab/tracer pairs applicants produced was used for detection of PAP in SULT reactions that are allowed to proceed to completion before reading. However, a continuous assay is the most desirable format for HTS because it allows accurate enzyme rate determinations and precludes the need for a quench step. FIG. 23 shows that the 3642 Ab and C8-PAP-F14 tracer can be used to continuously monitor SULT1E1 enzyme activity over time, allowing determination of enzyme rates with diverse substrates.

FIG. 23 provides graphs of continuous FPIA-based detection of SULT activity with diverse substrates. acceptor substrates (200 nM) were added to wells containing 30 mM phosphate (pH 7.4), 7 mM DTT, 0.8 mM MgCl₂, 75 mM NaCl, 0.5 mg/mL BGG, 2 uM PAPS, 200 ng SULT1E1-cHis, 1 nM C8-PAP-F14 Tracer, and 12.5 uL Ab 3642 in a total volume of 100 uL. Control reactions (top trace in each graph) lacked C-His-SULT1E1 and contained all other reaction components. The plate was incubated at room temp and polarization read at 1 minute intervals.

The top trace in each graph is a control reaction lacking SULT1E1, thus polarization does not change significantly, whereas in the reactions containing enzyme it decreases with time. The experimental setup was very similar to what might be done in an HTS setting: antibody and tracer were put into the SULT reaction mix, dispensed into a 384 well plate containing different acceptor substrates, and the reactions were started by the addition of SULT1E1-cHis. The plates were then read at regular intervals and polarization values plotted as a function of time. In reactions with known SULT substrates, the polarization decreased over time relative to control reactions lacking enzyme; as may be expected as enzymatically produced PAP displaces the tracer from Ab. Note that there is no significant change in polarization when no acceptor substrate is present (graph f) or if SULT1E1 is absent (top trace in each graph), indicating that the PAPS molecule is sufficiently resistant to non-productive chemical or enzymatic hydrolysis.

These results show that a generic, fluorescence-based activity assay for sulfotransferases is technically feasible. In these experiments, the cross reaction of the 3642 Ab with PAPS contributes significant background (i.e., decrease in polarization), limiting the dynamic range of the assay, but enzymatic rates can still be obtained from the linear portions of the velocity curves. The bar graph in FIG. 24 shows rates for each substrate calculated from linear portions of the velocity curves in FIG. 23; though not a precise assay at this point, this rank-ordering of substrates does correlate inversely with their published K_(m) values and with the substrate profile that applicants determined using purified SULT1E1 and the ³⁵S-PAPS radioassay (FIG. 24). Accordingly, FIG. 24 is a comparison of SULT1E1 acceptor substrate profiles determined using the FPIA-based assay and the ³⁵S-PAPS radioassay. Rates of FPIA-based reactions were calculated from linear portions of curves shown in FIG. 23. Acceptor substrates were used at 200 nM (FPIA) or 400 nM (³⁵S-radioassay).

Lastly, applicants used a known SULT inhibitor, DCNP, to show that the FPIA-based assay could be used to generate an inhibition curve (FIG. 25). Specifically, FIG. 25 is a graph showing inhibition of SULT1E1 by 2,6 Dichloro-4-nitrophenol (DCNP) measured with the FPIA-based assay. DCNP was serially diluted two-fold into wells in 46 uL of phosphate assay buffer (30 mM KPO₄ (pH 6.5), 0.5 mg/mL BGG, 15 mM DTT, 1.6 mM MgCl₂, 4 μM PAPS), followed by 50 μl of a 2× Antibody/tracer mix (5 uL 3642 Ab/2 nM Tracer C8-PAP-F14), and 200 ng of SULT1E in a total volume of 100 μl. The plate was incubated at room temp for 30 min, and read on the Tecan Ultra. ΔmP values were calculated by subtracting the SULT1E reactions from the no SULT1E controls. All values represent the mean of replicates.

The response of the FPIA assay to DCNP was validated by comparison with the ³⁵S-radioassay (data not shown); the K_(i) values determined with the two assay methods were 7.8 mM and 11 mM, respectively. Thus applicants have demonstrated that the assay can be used for detection of substrates and inhibitors—both of the key intended HTS applications.

Taken together, these results clearly establish feasibility for producing all of the components of the proposed FPIA based SULT assay: purified recombinant SULTs, antibody that selectively recognizes PAP in the presence of PAPS, and fluorescent PAP tracers whose binding and competitive displacement from Ab can be detected by significant changes in polarization. In addition, applicants were able to demonstrate that the assay reagents could be used to detect SULT activity in a continuous mode, very similar to how the assay may be used in an HTS setting, that the response to different substrates is similar to the standard radioassay, and that the assay can be used for detection of an inhibitor.

Accordingly, it is envisioned that an antibody, suitably a monoclonal antibody with approximately 10-fold greater affinity and selectivity for PAP will be produced that will enable development of an assay with suitable dynamic range and signal:noise for commercial HTS applications.

Example 5 Assay Systems

Although, the methods described herein may be utilized in a variety of different assay systems, in its simplest form, the present assay system comprises an assay receptacle in which the assayed reaction is carried out, and a detector for detecting the results of that reaction. In preferred aspects, the assay receptacle is selected from a test tube, a well in a multiwell plate, or other similar reaction vessel. In such cases, the various reagents are introduced into the receptacle and typically assayed in the receptacle using an appropriate detection system, described above such as a fluorescence polarization detector. In addition to a receptacle, a flat surface such as glass or plastic could also be used and the reaction components spotted onto the surface in a defined array (such as a microarray).

Alternatively, and equally preferred is where the reaction receptacle comprises a fluidic channel, and preferably, a microfluidic channel. As used herein, the term microfluidic refers to a channel or other conduit that has at least one cross-sectional dimension in the range of from about 1 micron to about 500 micron. Examples of microfluidic devices useful for practicing the methods described herein include, e.g., those described in e.g., U.S. Pat. Nos. 5,942,443, 5,779,868, and International Patent Application No. WO 98/46438, the disclosures of which are incorporated herein by reference.

In accordance with the above-described methods, it is envisioned that an enzyme mediated coupling reaction between a first and second reactant may be carried out in channels of a microfluidic device. As such, by using a microfluidics platform, it may be possible to mimic the compartmentalization of a eukaryotic cell. This method could then be used to monitor the activity of group transfer reactions catalyzed by enzymes in a more native environment, in the context of other proteins and with cellular components that may affect enzymatic activity. Therefore, data on the activity of enzymes that catalyze group transfer reactions and the consequences of their inhibition can be obtained in a setting that will more accurately reflect an in vivo environment.

It is envisioned that these assay systems may be capable of screening test compounds that affect enzymatic reaction of interest. Optionally, devices used in accordance with the present invention are configured to operate in a high-throughput screening format, e.g., as described in U.S. Pat. No. 5,942,443. In particular, instead of delivering potential test compounds to the reaction zone from a reservoir integrated into the body of the device, such test compounds are introduced into the reaction zone via an external sampling pipettor or capillary that is attached to the body of the device and fluidly coupled to the reaction zone. Such pipettor systems are described in, e.g., U.S. Pat. No. 5,779,868 (fully incorporated by reference). The sampling Pipettor is serially dipped into different sources of test compounds which are separately and serially brought into the reaction zone to ascertain their affect, if any, on the reaction of interest.

Movement of materials through the channels of these microfluidic channel networks is typically carried out using any of a variety of known techniques, including electrokinetic material movement (e.g., as described in U.S. Pat. No. 5,858,195 (fully incorporated by reference), pressure based flow, axial flow, gravity flow, or hybrids of any of these.

Example 6 Assay kit

Another embodiment of the invention is a kit for detecting and quantifying a donor product of a group transfer reaction or a catalytic activity generating the donor-product of a group transfer reaction. The general equation for the group transfer reaction includes a donor-X+acceptor→donor-product+acceptor−X, wherein the donor-product is detected by the general detection reaction: first complex+donor-product→second complex+displaced detectable tag. In its most simplest form, the kit for an FPIA immunoassay may include a macromolecule (i.e., antibody or an inactivated enzyme) and a tracer (displaced) and optionally the specific group transfer enzyme of interest. It is noted that the macromolecule and the tracer may either be separate or incorporated into one solution vessel.

The kit may also include components such as, an activated donor, a detectable tag, acceptor substrates, inhibitors, buffers, cofactors, stabilizing agents, a set of instructions for using the kit, or packaging and any combination thereof. In addition, the kit may be formatted for multiplex detection by using more than one antibody/detectable tag pair where the detectable tags can be differentiated on the basis of the observables they produce. The immunoassay may be used to detect the donor product or the catalytic activity generating the donor product.

In practicing the invention, it is encompassed that the kit may be used for screening a library for a molecule or a set of molecules, capable of contacting an enzyme, wherein the enzyme generates the donor-product in a group transfer reaction. The library may include at least one of a plurality of chemical molecules, a plurality of nucleic acids, a plurality of peptides, or a plurality of proteins, and a combination thereof; wherein the screening is performed by a high-throughput screening technique using a multi-well plate or a microfluidic system.

It is further envisioned that the macromolecule in the kit includes at least one of an antibody, a polypeptide, a protein, a nucleic acid molecule, an inactivated enzyme, and a combination thereof that is capable of contacting the donor-product with high affinity. It is further envisioned that the kit optionally include at least one of a sulfotransferase, a kinase or an UDP-glucuronosyl transferase, a methyl transferase, an acetyl transferase, a glutathione transferase, or an ADP-ribosyltransferase and combination thereof.

Although FPIA is a suitable mode of detection, also encompassed within the scope of the invention are kits designed to be used for detecting donor product or the catalytic activity generating the donor product through other means such as a homogenous assay, a homogeneous fluorescence intensity immunoassay, a homogeneous fluorescence lifetime immunoassay, a homogeneous fluorescence resonance energy transfer (FRET) immunoassay or a homogenous chemiluminescent immunoassay, or a non-homogenous assay such as enzyme-linked immunoassay (ELISA). In the case of a homogeneous fluorescence intensity immunoassay or a homogeneous fluorescence lifetime immunoassay, the kit could be composed of an antibody and fluorescent detectable tag where the intensity and/or lifetime of the detectable tag is different when it is bound to antibody and than it is free in solution. The difference in fluorescence; i.e., the assay signal, could be enhanced by modification of the antibody such that its interaction with the detectable tag results in a further change in its fluorescence properties; i.e., quenching, enhancement, or a change in the lifetime. In the case of a homogenous FRET immunoassay, the interaction of a first fluor associated with the detectable tag with a second fluor that is attached to the antibody—either directly or via associated binding molecules such as biotin and streptavidin—could result in the excitation of the second fluor (or the reverse), thereby generating a fluorescence emission at a wavelength different from that of the detectable tag. The second fluor could be a small organic molecule or a luminescent lanthanide probe. (It is noted that lanthanide emission is not fluorescence and is referred to as luminescence-based resonance energy transfer, or LRET). In the case of chemiluminescent detection, the detectable tag could be the donor product bound to one fragment of an enzyme used for chemiluminescent detection such as β-galactosidase. When the donor product-fragment-one complex is displaced from antibody by the donor product, it would then bind to fragment two of the enzyme, producing an intact, active enzyme that would be capable of producing a chemiluminescent signal with an appropriate substrate. In the case of an ELISA, the assay would not be homogenous, and would require donor product or antibody be immobilized to the surface of multiwell plates. A secondary antibody conjugated to a detection enzyme would also be included in this format.

All publications cited herein are hereby incorporated by reference in their entirety. In the case of conflict between the present disclosure and the incorporated publications, the present disclosure should control.

While the present invention has now been described and exemplified with some specificity, those skilled in the art will appreciate the various modifications, including variations, additions, and omissions that may be made in what has been described. Accordingly, it is intended that these modifications also be encompassed by the present invention and that the scope of the present invention be limited solely by the broadest interpretation that lawfully can be accorded the appended claims. 

1. An antibody produced against a donor-product of an enzymatically catalyzed group transfer reaction, wherein the antibody comprises the ability to preferentially recognize a donor-product in the presence of a donor molecule; wherein the enzyme catalyzing the group transfer reaction is a kinase; and wherein the antibody binds the donor-product, ADP with at least fifty-fold higher affinity than to ATP.
 2. The antibody of claim 1, wherein the antibody is generated using an immunogen made from nucleotide conjugated to a carrier protein.
 3. The antibody of claim 2, wherein the nucleotide is conjugated to a carrier protein at the N6 amino position of adenine.
 4. The antibody of claim 2, wherein the immunogen includes a linker region between the nucleotide and the carrier protein comprising a chemical formula of NH₂—X-Z, wherein X is a saturated or unsaturated chain of 2 to 20 carbons and Z is a functional group capable of covalently binding to a protein, and wherein the group includes an NH₃. 